Classifications

• • G—PHYSICS
  • G07—CHECKING-DEVICES
  • G07B—TICKET-ISSUING APPARATUS; FARE-REGISTERING APPARATUS; FRANKING APPARATUS
  • G07B17/00—Franking apparatus
  • G07B17/00016—Relations between apparatus, e.g. franking machine at customer or apparatus at post office, in a franking system
  • G07B17/0008—Communication details outside or between apparatus
• • G—PHYSICS
  • G06—COMPUTING; CALCULATING OR COUNTING
  • G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
  • G06Q30/00—Commerce
  • G06Q30/018—Certifying business or products
• • G—PHYSICS
  • G07—CHECKING-DEVICES
  • G07B—TICKET-ISSUING APPARATUS; FARE-REGISTERING APPARATUS; FRANKING APPARATUS
  • G07B17/00—Franking apparatus
  • G07B17/00016—Relations between apparatus, e.g. franking machine at customer or apparatus at post office, in a franking system
  • G07B17/0008—Communication details outside or between apparatus
  • G07B2017/00137—In a LAN
• • G—PHYSICS
  • G07—CHECKING-DEVICES
  • G07B—TICKET-ISSUING APPARATUS; FARE-REGISTERING APPARATUS; FRANKING APPARATUS
  • G07B17/00—Franking apparatus
  • G07B17/00016—Relations between apparatus, e.g. franking machine at customer or apparatus at post office, in a franking system
  • G07B17/0008—Communication details outside or between apparatus
  • G07B2017/00145—Communication details outside or between apparatus via the Internet
• • G—PHYSICS
  • G07—CHECKING-DEVICES
  • G07B—TICKET-ISSUING APPARATUS; FARE-REGISTERING APPARATUS; FRANKING APPARATUS
  • G07B17/00—Franking apparatus
  • G07B17/00016—Relations between apparatus, e.g. franking machine at customer or apparatus at post office, in a franking system
  • G07B17/0008—Communication details outside or between apparatus
  • G07B2017/00153—Communication details outside or between apparatus for sending information
  • G07B2017/00161—Communication details outside or between apparatus for sending information from a central, non-user location, e.g. for updating rates or software, or for refilling funds
• • G—PHYSICS
  • G07—CHECKING-DEVICES
  • G07B—TICKET-ISSUING APPARATUS; FARE-REGISTERING APPARATUS; FRANKING APPARATUS
  • G07B17/00—Franking apparatus
  • G07B17/00016—Relations between apparatus, e.g. franking machine at customer or apparatus at post office, in a franking system
  • G07B17/0008—Communication details outside or between apparatus
  • G07B2017/00153—Communication details outside or between apparatus for sending information
  • G07B2017/00169—Communication details outside or between apparatus for sending information from a franking apparatus, e.g. for verifying accounting

Definitions

• the present invention relates to an electronic franking machine.
• Franking machines conventionally include franking means which make it possible to affix a franking mark on a courier.
• Means for controlling and managing these postage means make it possible to calculate the postage value and to create the mark affixed to the mail.
• Such machines also include postage accounting means. Generally, they comprise a counter known as ascending whose value, with each impression of a franking mark, is increased by the amount of the value of this franking, and / or a counter known as descending, whose value is decreased by this same postage value.
• the so-called ascending counter thus represents the total value of postage printed by the machine since it was put into service, while the so-called descending counter indicates the available credit, not yet consumed since the last recharging of the machine in monetary units.
• Such a system has the drawback of taking a long time to implement and of using a card which passes between the center and the site on which the franking machine is used.
• a telematics terminal may be available directly on the user's site, this terminal being connected to the control center by means of a modem, communication passing through the public telephone network .
• Each memory card, associated respectively with a franking machine can be inserted into the terminal and recharging data, sent by the center, are written on the memory card. This card is then conventionally inserted into the associated franking machine.
• the object of the present invention is to provide a franking machine and a method for carrying out transactions between the control center and the franking machine, which in particular allow these transactions to be carried out quickly and securely.
• the electronic franking machine comprises franking means and means for counting franking.
• this franking machine comprises means of connection, via a computer communication network, to a central server of a computerized control center, and means forming a computer server suitable for sending and receiving requests and computer responses for carrying out transactions with the central server, the transactions being chosen from at least one reload of the postage accounting means, a file transfer forming statements of the posting means and a postage cycle.
• the franking machine can be likened to a computer terminal which can directly exchange information with a central server of the control center, for example by a communication network of the Internet type.
• Hyper Text Transfer Using a communication protocol, such as for example the hypertext transport protocol (in English Hyper Text Transfer
• the connection of the franking machine to the central server directly by a computer network possibly makes it possible to require authorization from the center for each franking cycle and no longer for an overall franking value stored on the machine in the meter. says descending, then spent as successive cycles of postage.
• the computer server means comprise as many computer servers different than types of transaction to be carried out between said machine and the central server.
• the computer servers are dedicated to one operation and only one so that a specific authorization can be granted to each server of the franking machine by the central server for carrying out a transaction.
• the franking machine comprises means for calculating inspection data suitable for authenticating the state of the accounting means.
• the inspection data calculation means are adapted to produce a cryptogram from data from the recording means and from a secret digital key associated with a calculation algorithm.
• the digital key which can be initialized at the factory, allows you to sign the transmitted inspection data.
• It can be dynamic and can be modified over time, for example with each new transaction.
• a method of carrying out a transaction between a franking machine according to the invention and a central server of a computerized control center, implemented on said franking machine comprises the following steps :
• this method further comprises a step of transferring inspection data adapted to authenticate the state of the accounting means of the machine.
• This step allows the central server to verify the integrity of the data and to detect any fraud or malfunction of the franking machine.
• this method of carrying out a transaction comprises two steps for transferring inspection data, one before and the other after the completion of the transaction, which makes it possible to carry out the transaction only if the integrity of the different counters is checked and to check that the different parameters transmitted during the transaction have been correctly memorized.
• a method of carrying out a transaction between a franking machine according to the invention and a central server of a computerized control center, implemented on the central server comprises the following steps:
• This method of carrying out a transaction implemented on the central server has advantages and preferential characteristics symmetrical to those described above for the method of carrying out a transaction implemented on the franking machine.
• the present invention also relates to a computer communication network comprising at least one franking machine conforming to the information and a central server of a computerized control center.
• This communication network makes it possible to connect a franking machine to a computerized control center in real time to allow the carrying out of a certain number of remote transactions of the meter reload type, meter readings, completion of a cycle of postage or other transactions.
• FIG. 1 is a block diagram illustrating a communication network according to an embodiment of the invention
• FIG. 2 is a diagram illustrating a franking machine according to an embodiment of the invention
• FIG. 3 is a diagram illustrating the different layers of the connection of a postage meter to a computer communication network
• FIGS. 4, 5 and 6 are graphs illustrating the method of carrying out a transaction in accordance with an embodiment of the invention, respectively for a meter reload, a meter reading and a franking cycle.
• FIG. 1 illustrates a computer communication network 1 which comprises several franking machines 10 which are connected by the network 1 to a central server 20 of a computerized control center 2.
• Certain franking machines 10, numbered 3, ..., N, can be directly connected to the communication network 1.
• franking machines 10 numbered 1, 2 Z
• a communication network local computer 3 this local network 3 being connected to the central server 20 by an intermediate local server 30.
• Such a configuration is particularly well suited when several franking machines 10 are present on the same site 4, for example inside a company, the franking machines 10 being connected to the local network of the company, of the network type. Ethernet.
• the central server 20 and the server 30 of the local network 4 are typically computers comprising a microprocessor, a read only memory adapted to record programs for communicating via the communication networks 1, 3 with different servers of these networks and a random access memory which records the variables modified during the execution of these programs.
• the franking machines 10 conventionally comprise, as illustrated diagrammatically in FIG. 2, franking means 11 which for example comprise a print head situated above a guide plate of the object on which the mark postage must be affixed.
• the machine 10 can also include, as peripherals, a keyboard 12 allowing the user to enter certain parameters necessary for franking and a balance 13 for weighing objects to be franked.
• Electronic control and management means are generally adapted to control the franking means 11 by means of internal electronic circuits controlled by a microcontroller provided with franking management software.
• the machine 10 also includes accounting means
• these counters 17 could be housed in a sealed box 15, at the periphery of the franking machine 10 proper (in English Postal Security Device or PSD).
• PSD English Postal Security Device
• the secure memory 17 makes it possible to store recharging codes for the machine 10, a set of digital keys and an algorithm for calculating a cryptogram from data from accounting means 17 and a digital key. These stored data can be transferred at least in part during an initialization phase of the franking machine from a smart card 16 to the secure memory 17 integrated in the franking machine 10.
• a set of recharging codes is also stored, these recharging codes being adapted to unlock the machine when a valid recharging code is transferred by the central server.
• the formats of smart cards 16 or 17 comply with the ISO standard. They are fitted with a re-writable non-volatile RAM type microcircuit, EEPROM type or equivalent.
• the franking machine 10 comprises means of connection 18, 19, via the computer communication network 1, to the central server 20 of the computerized control center 2.
• a stack of TCP / IP protocols is implemented in the franking machine 10 which allows access to known means such as internet or ethernet using standard connections 18, 19.
• This computer network model comprises in known manner a transport layer 21 called TCP (in English Transmission Control Protocol) above the network or internet layer 22 called IP (in English Internet Protocol).
• TCP in English Transmission Control Protocol
• IP in English Internet Protocol
• a link layer 23, of the SLIP type in English Sériai Line
• This physical layer comprises either an Ethernet interface 19 when the machine 10 is connected to the local network 3, or a connection of the RS 232 type 18 in the EIA standard (in English Electronic Industries
• TCP / IP protocol is well known to those skilled in the art of computer communication networks and does not need to be described in detail here.
• This TCP / IP protocol thus provides access to communication networks in a standardized manner, and in particular to the Internet.
• This protocol is integrated with a real-time kernel and its activation in the machine is conditional on the launch of the real-time kernel.
• serial layer 24 can use a connector through which there is access to the internal circuits of the machine 10, this connector being able to be connected to a computer in the center 2 in order to perform an initialization operation.
• the connector of the serial layer 24 can be masked by a tamper-proof protective envelope.
• TCP / IP protocol makes it possible to implement in the machine 10 means forming a computer server 31 suitable for transmitting and receive requests and computer responses to carry out transactions with the central server 20 via the communication network 1.
• HTTP central server 31 with specific functions for the different functions performed by the machine 10. These functions or transactions performed by the machine 10 can be chosen in a nonlimiting manner from:
• a franking cycle 34 which makes it possible to calculate and create the franking mark to be affixed from a software for calculating and ordering franking, - possibly updating 35 of a database grouping the rates applicable,
• peripheral elements 36 such as the keyboard 12 or the scale 13
• an update 38 generally partial, of the software for calculating and controlling postage
• the HTTP computer server 31 thus comprises as many separate computer sub-servers 32 to 41 as there are types of transaction to be carried out between the machine 10 and the central server 20.
• Access to all or some of these functions can be combined with transaction codes which authorize access to one or other of the servers 31-41.
• the franking machine 10 may include means for calculating inspection data 25 adapted to authenticate the state of the accounting means 17.
• inspection data calculation means 25 are adapted to produce a cryptogram calculated from data stored in the accounting means 17 and from one of the digital keys associated with the calculation algorithm.
• the method firstly comprises a step of connection E1, E21, E41 of the franking machine 10 with the central server 20.
• the machine first goes into communication mode, then calls the central server via the computer network 1.
• a step E2, E22, E42 of transferring an identifier makes it possible to address to the server 20, information allowing the identification of the machine 10 among all the franking machines which can communicate with the central server 20 via the computer communication network. 1.
• This identifier can be, by way of nonlimiting example, a frame number or machine number determined in the factory.
• the method then comprises on the central server side 20 an identification step E3, E23, E43 of the franking machine 10, by comparing the identifier transmitted with the identifiers stored on the central server 20.
• a step of requesting inspection data E4, E24, E44 is set in work for the franking machine 10.
• a step of transferring inspection data E5, E25, E45 is then implemented on the franking machine, to authenticate the state of the accounting means 17 of the machine 10.
• a cryptogram is thus calculated using an algorithm using a secret key and data from the counters 17.
• the cryptogram is calculated by the machine, for example from a DES type algorithm.
• the secret key and the cryptogram are then transferred to the central server 20.
• This transfer step is followed by a blocking step E6, E26, E46 of the franking machine which locks, which prohibits its use until the initialized transaction has not been carried out correctly.
• the franking machine 10 can be locked in various ways.
• the value of the latter is transferred to a temporary counter and the down counter itself of the franking machine 10 is set to zero which blocks the machine.
• the machine is credited by adding a sum of money to the temporary counter.
• the machine is released by transferring the value of the temporary counter to the descending counter of the machine.
• a step of transferring a transaction code E7, E27, E47 is then implemented on the franking machine 10 to authenticate the requested transaction.
• This transaction can be either a request to reload the postage meter 17 accounting means (figure 4), that is to say the down counter, or a request for remote reading (figure 5) when the required transaction is a file transfer forming statements of the accounting means 17, ie a franking request (FIG. 6), for example for a certain number of letters to be franked with a given value, when the required transaction is a franking cycle.
• the method further comprises a step E48 of requesting an amount of franking, entered for example by the user by means of the keyboard 12 of the franking machine 10.
• the method then comprises at the central server 20 a step E8, E28, E49 of verification of the received cryptogram.
• the cryptogram is recalculated from the data received and from the digital key, then the central server 20 verifies that the calculated cryptogram is indeed identical to the cryptogram transferred by the machine 10 in order to authenticate the state of the accounting means 17 of machine 10 if the two cryptograms are identical.
• a reload code is transferred during a transfer step E10.
• This reloading code is chosen from a list of codes prerecorded both at the level of the central server 20 and in the secure memory 17 of the machine 10, this reloading code being associated with a reloading value of the counter.
• This way of proceeding avoids any transfer of monetary value on the computer network for reloading the meter.
• Applicant for details relating to the reloading of a downward counter from prerecorded reload codes.
• the central server forms a request to request that the files to be read remotely be transferred in a step E29.
• the central server 20 sends franking information during a transfer step E50, which will allow the machine to compose the postage mark to be affixed on each mail.
• the method may further include a step E9, E32 of transferring data from a next transaction, such as for example a new digital key for calculating the algorithm for authenticating the counters.
• this step of transferring data E9 for a next transaction can be implemented before the completion of the transaction, or alternatively, after the completion of the transaction, as illustrated in FIG. 5.
• the transaction is then carried out on the postage meter.
• the descending counter is reloaded at a recharging step E12 from the recharging code received, as a function of a value prerecorded opposite this code in the secure memory 17.
• files centralizing the data from the counters 17 are transmitted to the central server 20 during a transfer step E30.
• the remote reading files can be directly written and transferred in hypertext markup language (in English HyperText Markup Language or HTML).
• a verification step E31 of the data received is also implemented on the central server 20 to verify that the remote reading has been correctly carried out.
• the information transmitted by the server makes it possible, as illustrated in FIG. 6, to frank one or more letters during a franking step E53 by affixing a franking mark created in the usual way from a certain number of parameters (destination, weight of the mail, address of the sender, registered mail, ).
• This postage is also accompanied by an incrementation of the ascending counter and a decrementation of the descending counter by the postage value corresponding to the postage cycle executed.
• the method further comprises after the completion of the transaction, new steps for requesting and transferring inspection data E11, E14, E33, E34, E52, E55 to authenticate the state of the accounting means 17 of the machine 10 once the transaction is completed.
• This authentication is particularly important during a reload of the counter or a franking cycle and can possibly be omitted when the counters have not been a priori modified by the transaction, as is the case during a remotely read.
• a step of verifying the data received E15, E35, E56 is implemented to receive and verify the cryptogram associated with the digital key used for its calculation.
• the verification of the cryptogram is adapted to authenticate the state of the accounting means once the transaction has been carried out by the franking machine.
• This verification step is implemented in the same way as the verification step E8, E28, E49 described above.
• the franking machine 10 is unlocked in an unblocking step E13, E37, E54.
• This unlocking is authorized when a valid reload code is transmitted by the central server 20 to the machine 10.
• the machine can memorize a set of reload codes, possibly ordered.
• the franking machine verifies that this code is part of the set of stored codes, and possibly, that it is identical to a predetermined code in the order of browsing of the set of stored codes.
• the transaction is a reloading of the counters as illustrated in FIG. 4, the reloading code transferred to step E10 makes it possible to unlock the machine 10.
• a specific step of transferring a reload code E36, E51 is implemented on the central server 20.
• This change of reload code for each transaction with the central server 20 makes it possible to strengthen the security of access to the server.
• central 20 via the communication network 1 to prevent franking machines 10 from connecting without authorization to this server 20.
• a last step E16, E38, E57 makes it possible to disconnect the franking machine 10 from the communication network 1 by ending the communication mode.
• This method according to the invention thus makes it possible to carry out various transactions between a central server 20 and a franking machine without requiring a material transfer from one to the other.
• the machine 10 in which a franking cycle as illustrated in FIG. 6 is implemented, the machine 10 must systematically request authorization from the central server 20 for franking.
• the information transmitted by the central server 20 for the franking cycle can include an indication of reloading of the down counter, with a value just equal to the value necessary to carry out the franking cycle. Once the latter is finished, the descending counter returns to its initial value, for example a zero value.
• the central server 20 manages the accounting of the machine, the latter no longer managing money directly.

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• Business, Economics & Management (AREA)
• Physics & Mathematics (AREA)
• General Physics & Mathematics (AREA)
• Marketing (AREA)
• Accounting & Taxation (AREA)
• Development Economics (AREA)
• Economics (AREA)
• Finance (AREA)
• Entrepreneurship & Innovation (AREA)
• Strategic Management (AREA)
• General Business, Economics & Management (AREA)
• Engineering & Computer Science (AREA)
• Theoretical Computer Science (AREA)
• Devices For Checking Fares Or Tickets At Control Points (AREA)
• Management, Administration, Business Operations System, And Electronic Commerce (AREA)
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• 1999
  • 1999-05-05 FR FR9905705A patent/FR2793332B1/fr not_active Expired - Fee Related
• 2000
  • 2000-03-17 DE DE1173832T patent/DE1173832T1/de active Pending
  • 2000-03-17 WO PCT/FR2000/000660 patent/WO2000068895A1/fr not_active Application Discontinuation
  • 2000-03-17 CA CA002373053A patent/CA2373053A1/fr not_active Abandoned
  • 2000-03-17 EP EP00910980A patent/EP1173832A1/de not_active Withdrawn
  • 2000-03-17 US US09/959,693 patent/US7113928B1/en not_active Expired - Fee Related
• 2002
  • 2002-06-27 HK HK02104793.9A patent/HK1043227A1/zh unknown

Non-Patent Citations (1)

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