FR2917207A1 - DOMESTIC PRINTING DEVICE COMPRISING CONTACTLESS PERSONALIZATION MEANS - Google Patents

Abstract

The invention relates to a printing device comprising a path (51-54) for scrolling paper and at least one antenna (AC1-AC7) having a range covering all or part of the scrolling path, making it possible to write data in a contactless integrated circuit. Application to the customization of integrated circuits encased in printable sheets.

Description

PRINTING DEVICE COMPRISING PERSONALIZATION MEANS WITHOUT

CONTACT

  The present invention relates to the customization of contactless integrated circuits encased in printable sheets. In recent years, the development of NFC (Near Field Communication) contactless integrated circuits has opened the way for many so-called "contactless" applications. The most popular applications of the public are the contactless bank card, the contactless electronic wallet, the contactless access control card, the identity card or the contactless electronic passport, the electronic business card without contact, etc. These integrated circuits also make it possible to produce contactless electronic tags for product identification, inventory management, goods tracking, etc. They have the advantage of being electrically powered by a magnetic or electric field, and thus not require an independent power source.

  The reduction in manufacturing costs and the technological progress of the semiconductor industry now make it possible to make contactless integrated circuits of very small thickness, for example a few micrometers to a few tens of micrometers, and to incorporate them into thin media such as paper sheets, cards, envelopes, self-adhesive labels, photo paper, etc. Thus, opens a new field of application intended for the general public which includes the sale of media of the aforementioned type, which the consumer can customize to

  by typing data in contactless integrated circuits. By way of example, FIG. 1 represents a sheet of paper 1 comprising pre-cut lines 2 delimiting detachable areas 3 making it possible to produce contactless business cards. In each detachable zone 3, the sheet comprises a non-contact integrated circuit 4 in the form of a semiconductor chip, as well as an antenna coil 5 connected to the integrated circuit 4. The integrated circuit 4 and the antenna coil 5 are preferably embedded within the sheet itself at the time of its manufacture and are thus seen here by transparency. The antenna coil 5 may be a separate element of the integrated circuit 4, as seen in the figure, but may also be performed on the semiconductor chip according to the so-called "coil on chip" technique. The integrated circuit 4 comprises an erasable and electrically programmable memory which is accessible for reading and writing via commands addressed to it via its antenna coil 5. In order to produce contactless business cards, the The user places the sheet 1 in a home printer and prints a pattern and / or information, such as his name and address and a color logo. The user then separates the detachable areas 3 to obtain the visit cards themselves, each comprising a contactless integrated circuit. Then, the user customizes each business card by writing data to it using an NFC reader. Note that various NFC players are commercially available, some being integrated into mobile phones or personal assistants (PDAs), others being sold as peripherals to connect to a personal computer. The

  personalization data can be identification data, for example surname, first name and contact information of the user, databases (contact list for example), files, application programs, etc. This personalization step can be slow and impractical, especially if the user wants to make many business cards. In addition, the user may inadvertently perform a wrong personalization of a business card, especially if he simultaneously personalizes several business cards with different printed patterns and different personalization data. The same risk of error at the time of personalization arises with envelopes or photos containing contactless integrated circuits. Thus, it may thus be desirable to provide a method for facilitating the writing of data in a contactless integrated circuit encased in a printable sheet. For this purpose, an embodiment of the invention relates to a paper printing device comprising a paper scroll path and at least one antenna having a range covering all or part of the scrolling path and making it possible to write data. in a contactless integrated circuit. According to one embodiment, the device comprises several antennas each arranged opposite a portion of the scroll path.

  According to one embodiment, each antenna has a communication field of limited range smaller than the extent of the scrolling path and not covering the communication field of the other antennas.

  According to one embodiment, the device comprises an antenna having an extended communication field covering all or part of the paper scroll path.

  According to one embodiment, the device comprises an antenna having a communication field covering a paper receiving tray. According to one embodiment, the device comprises an antenna secured to a movable member of the printing device. According to one embodiment, the movable member is a print head. According to one embodiment, the antenna is an antenna coil configured to emit a magnetic field. According to one embodiment, the device comprises at least one non-contact integrated circuit reader electrically connected to at least one antenna. According to one embodiment, the device 20 comprises at least one contactless integrated circuit reader connected to at least two antennas via switches. An embodiment of the invention also relates to a printing system comprising a printing device according to an embodiment of the invention, and a programmable device configured to supply the printing device with data to be written in at least one contactless integrated circuit. According to one embodiment, the programmable device is configured to send to the printing device commands for stopping the training of a sheet in the scroll path, in order to provide pauses of sufficient duration to write. data in a contactless integrated circuit encased in the sheet.

  According to one embodiment, the programmable device is configured to send to the printing device a print file comprising commands for stopping the training of a sheet in the scrolling path, in order to provide breaks for sufficient time to write data in a contactless integrated circuit encased in the sheet. According to one embodiment, the programmable device is configured to detect in real time the presence of a non-contact IC in a moving sheet in the paper path. According to one embodiment, the programmable device is configured to direct the movement of a sheet in the unprinted scroll path of the sheet, in order to write data into at least one contactless integrated circuit encased in the sheet. According to one embodiment, the programmable device is configured to transmit anti-collision commands via the antenna, in order to write data to a plurality of non-contact integrated circuits in the antenna's communication field. An embodiment of the invention also relates to a method of writing data in a contactless integrated circuit integrated in a sheet, comprising the steps of providing a paper printing device comprising a paper scroll path, arranging in the printing device at least one antenna having a range covering all or part of the scrolling path, arranging the sheet in the scrolling path, and using the antenna to write the data in the integrated circuit.

  According to one embodiment, the method comprises a step of providing several antennas each arranged opposite a portion of the scroll path.

  According to one embodiment, each antenna has a communication field of limited range smaller than the extent of the scrolling path and not covering the communication field of the other antennas.

  According to one embodiment, the method comprises a step of providing an antenna having an extended communication field covering all or part of the scroll path. According to one embodiment, the method comprises the steps of providing an antenna having a communication field covering a paper receiving tray, and writing data in the contactless integrated circuit during the scrolling of the sheet or after the scrolling of the sheet, when the sheet is immobilized on the receiving tray. According to one embodiment, the method comprises a step of providing an integral antenna of a movable member of the printing device. According to one embodiment, the movable member is a print head. According to one embodiment, the method comprises the steps of immobilizing the sheet in the scroll path, and writing data into the contactless IC while the sheet is immobilized. According to one embodiment, the method comprises the steps of sending to the printing device a print file comprising commands to stop the training of the sheet in the path of

  scrolling, and write data in the contactless integrated circuit while the sheet is immobilized. According to one embodiment, the method comprises a step of detecting in real time the presence of the contactless integrated circuit in the sheet during the movement of the sheet in the scroll path. According to one embodiment, the method comprises a step of using an antenna coil emitting a magnetic field to write data in a contactless integrated circuit. According to one embodiment, the method comprises the steps of providing at least two antennas, and alternately connect the one and the other antennas to a contactless integrated circuit reader, via switches. According to one embodiment, the method comprises the steps of issuing anti-collision commands via the antenna motion, and writing data in several non-contact integrated circuits found in the communication field of the antenna. Exemplary embodiments of the invention will be described in the following with reference to non-limiting illustrations to the attached figures among which: - Figure 1 previously described is a paper sheet including integrated circuits without contact; FIG. 2 is a diagrammatic top view of an exemplary embodiment of a printer according to the invention; Figure 3 is a sectional view of the printer of Figure 2 taken along a sectional plane AA '; FIG. 4 is the electrical diagram of a printing and personalization system including the printer of FIG. 2; - Figure 5 is a partial sectional view of another embodiment of a printer according to the invention; FIG. 6 is a schematic top view of yet another embodiment of a printer according to the invention; FIG. 7 represents a non-contact integrated circuit architecture; FIG. 8 represents an architecture of a contactless integrated circuit reader; and FIG. 9 represents an alternative embodiment of a personalization element present in the printer of FIG. 2. The invention provides for arranging one or more customization antennas for integrated circuits in the paper scrolling path. of a printer, for simultaneously or sequentially implementing a sheet printing step and a data writing step in a contactless integrated circuit embedded in the sheet. In the following description, the term "sheet", "sheet of paper" or "paper" will be used for convenience and for the sake of simplification of the language to denote a printable medium comprising one or more contactless integrated circuits and which may be inserted into a home printer for printing. Thus, in the description as in the claims, these terms are not limiting in nature and generally designate any support 30 pre-cut or not, of any format compatible with domestic printers (A4, A5, letter, postcard format, custom format , etc.), including single-layer paper, multilayer paper, card, card stock, glossy paper, photo paper, label

  self-adhesive on a backing sheet, self-adhesive paper, printable synthetic material, etc. Figures 2 and 3 show schematically an embodiment of a home printer 50 according to the invention, respectively by a top view and a sectional view along a plane AA '. The printer 50 shown here is an ink jet printer and is connected to a personal computer 8. The printer 50 includes a paper insertion slot 51, a print head 52 slidably mounted on a guide rail 53, a tray 54 for receiving printed sheets, for example the sheet of paper 1 shown in FIG. 1, a mechanism 59A for driving the print head 52 along the rail 53 and a drive mechanism 59B for driving the paper in a paper scroll path. The mechanisms 59A, 59B are not shown in Figures 2 and 3 for the sake of legibility of the diagrams but are shown in block form in Figure 4 described below.

  Slot 51 and drive mechanisms 59A, 59B are sized in the usual manner to allow various sheets of paper to be driven in the path of travel, which extends approximately from insertion slot 51 to end of the receiving tray 54. A print controller 58 controls the print head 52 and the drive mechanisms 59A, 59B. The controller 58 is connected to an input / output interface 6, for example a USB hub or any other known type of interface (IEEE1394, 802.11 ...) The interface 6 is connected to the personal computer 8, so that the printer can send print data to the controller 58. The printer is further provided with a non-contact data writer. This body includes

  antenna coils ACi, here 7 antenna coils AC1 to AC7, each coil being here connected to a contactless integrated circuit reader RDi, respectively RD1 to RD7. The antenna coils ACi are arranged in the paper path, that is to say substantially above or below it so as not to hinder the passage of the paper. The antenna coils ACi are for example arranged under the plate 54 or inside thereof, as represented in FIG. 3. Each antenna coil ACi has a communication perimeter, that is to say a magnetic field radiation zone within which communication can be established with a contactless integrated circuit.

  The spacing between the antenna coils can be chosen to be greater than or equal to the communication perimeter of each coil if it is desired that the communication perimeters do not overlap, in order to avoid conflicts during the simultaneous writing of several integrated circuits. This choice depends in practice standardized templates that will be retained in the future for the arrangement of integrated circuits in sheets of paper or equivalent. In this embodiment, the RD1-RD7 readers are arranged near the antennas, in order to limit the length of the wires connecting them to the latter and the resulting ohmic losses. Each reader is also connected to the interface 6 of the printer via an SBS serial bus and a bus controller 7. During its run in the scroll path, the sheet of paper 1 is located and vis-à-vis the print head 52 and vis-à-vis the AC1-AC7 antenna coils. Sheet 1 comprises contactless integrated circuits 4 (see Fig. 1) and RDi readers

  can communicate inductively with these integrated circuits to write data there while the sheet is in the scrolling path. FIG. 4 represents the electrical diagram of a printing and personalization system according to the invention comprising the printer 50 and the personal computer 8. Each reader RDi here comprises an interface circuit IC 1, respectively IC 1 to IC 7, enabling it to communicate with the personal computer 8 via the SBS bus, the controller 7 and the interface 6. The RDi readers are for example MICROREAD components marketed by the applicant, comprising an integrated UART interface used as an ICi interface circuit .

  The computer 8 comprises a mass memory 81 (hard disk, CD ROM ...) in which is stored a program SW management of the present application. The SW program includes high level layers including the human / machine interface as well as low level layers including a PRDR printer driver and an ATDR customization driver. The printer driver PRDR provides the supply of print files compatible with the printer processor 58 of the printer and the ATDR personalization driver provides data writing in the integrated circuits 4 present in the sheet of paper 1 by RDi readers and via the interface 6, the bus controller 7 and the SBS bus. For this purpose, the ATDR driver includes various libraries, including a library of Bibi templates, a Bib2 configuration library, and a Bib3 command library. The Bibi template library contains descriptive data of various templates corresponding to various types of paper sheets.

  incorporating contactless integrated circuits. The descriptive data specifies in particular the location of the integrated circuits within each template. Templates can be small or large sheets containing a single contactless IC (including envelopes, cards, photo paper, etc.) and sheets with multiple contactless ICs , such as the sheet of paper 1.

  The Bib2 configuration library contains a description of various printer models and, for each printer model, information about the arrangement of antenna coils ACi in the paper scroll path. For example, the printer 50 shown in FIGS. 2 and 3 comprises two rows of antenna coils offset in the running direction of the paper sheet 1. A first row comprises the antenna coils AC1, AC2, AC3 and a second row comprises the antenna coils AC4, AC5, AC6 and AC7. This information is recorded in the Bib2 library, as are the distances between the antenna coils and their position in the scrollpath. As will be seen later, a printer may also include only one antenna coil having an extended communication field. In this case the configuration data only indicates the presence of this antenna coil and it is not necessary that they specify its location in the scrollpath.

  The library Bib3 contains at least one set of CMD commands compatible with the integrated circuit (s) without contact present (s) in the sheet to customize. This library may also contain a list of contactless integrated circuits of different types that may be embedded in various sheets in

  depending on the origin of these sheets and / or their manufacturer, and a set of commands appropriate to each type of integrated circuit. Each set of commands comprises, for example, commands for interrogating, reading and writing a contactless integrated circuit, which are in themselves known. Anti-collision controls may also be provided for reasons that will appear later. In order to illustrate the operation of the printing system, it will now be assumed that a user wants to customize the sheet of paper 1 shown in FIG. 1. After having defined the printing data (color, text, graphic) of the sheet in a SFilel source file, the user opens a control window (user interface) that the program SW displays on the computer screen, and chooses between a "printing with customization" and "normal printing" mode.

  The user here selects the "printing with personalization" mode and communicates to the program SW, by means of the control window, the personalization data to be written in the integrated circuits embedded in the sheet. As indicated above, this data can be of various types, such as identification data, addresses, programs or application parameters, files, application activation codes, and so on. Preferably, the control window is designed to help the user to not invert personalization data. For example, the program SW displays in the control window the graphical representation of the source file SFilel by displaying on the computer screen the zones 3 of the sheet 1, and superimposes on this display the personalization data.

  concerning each zone. This data can be displayed in clear or indirectly, for example by displaying a file name containing the data, a title that the user has conferred on the data (for example: "contact list N 2"). Thus, the user clearly sees what personalization data he will write in each zone 3 of the sheet 1. After completing this preparatory step, the user triggers the process of printing and customization. The program SW then supplies the source file to be printed SFilel to the printer driver PRDR and simultaneously generates a source file SFile2 containing the customization data communicated by the user, which it provides to the personalization pilot ATDR. The PRDR printer driver transforms the source file into an Ifilel print file that can be executed by the print processor 58. Since the "print with customization" mode has been activated, the PRDR driver communicates this file to the printer driver. ATDR customization instead of sending it directly to the print processor. Using the data present in the files IFilel, SFile2 and in libraries Bibl, Bib2, the ATDR driver executes algorithms allowing it to determine: - the time required for the write operation in each contactless integrated circuit 4, in depending on the amount of data to be written (typically from a few tens of milliseconds to a few seconds), and - the times when the contactless integrated circuits 4 will be writable during the scrolling of the paper in the printer, that is to say say the moments when they will be in the field of communication of one of the antenna coils.

  If the print speed is too fast to write data to integrated circuits on the fly, the PRDR driver modifies the Ifilel print file by incorporating one or more timed shutdown commands without ejecting paper, namely HALT commands (t) with "t" the desired delay time. The modified print file is renamed "IFile2" and is sent to the print processor 58 instead of the IFilel file.

  The print processor 58 controls the print head 52 and the drive mechanisms 59A, 59B according to the data in the IFile2 print file, which it executes step by step. When the print processor encounters a timed stop command HALT (t), it sends a print suspension confirmation information to the ATDR driver, which then takes control of the RDi drives, accesses the integrated circuits to be customized through the game. of CMD commands, and writes the customization data provided by the user. According to the arrangement of the contactless integrated circuits in the sheet being printed, and the arrangement of the antenna coils ACi in the printer, several RDi readers can be simultaneously requested to write at the same time data in different circuits. integrated. By driving the paper in the scrolling direction, the integrated circuits that have not yet been customized are found at one time or another in the communication field of one of the antenna coils, so that all Integrated circuits can be written between the beginning and the end of the printing process. Those skilled in the art will note that template management using the Bibi library can be replaced by dynamic detection of the presence of circuits.

  contactless integrated 4 in the field of communication of antenna coils ACi. In such an embodiment, the operation of the print processor 58 is modified so that the latter reacts to temporary stop commands that are sent in real time by the ATDR personalization driver instead of being inserted in the file. printing. Such dynamic detection can be implemented by applying the rules of the art, for example by sending cyclically, from each antenna coil ACi, interrogation commands to which the integrated circuits in the communication field of the circuits respond. antenna coils. The integrated circuits can also be detected in the manner taught by the application WO 03/052672 in the name of the applicant, by monitoring the variations of the impedance of the antenna circuit of each reader RDi. The possibility may also be offered to the user to perform the printing of the sheet and the writing of personalization data in two passages of the paper, in any order to the choice of the user. The user may, for example, wish to print the sheet before having defined the data to be written in the contactless integrated circuits. The user may also wish to erase personalization data previously written in the integrated circuits to replace them with new data, or add new personalization data, while the sheet has already been printed. In this case, the PRDR driver provides the print processor with an Ifile2 print file containing no data to print and containing only scroll commands on the sheet as well as commands for temporarily stopping scrolling when customization are achieved. FIG. 5 is a schematic sectional view of an alternative embodiment

  of the previously described printer, in which a contactless integrated circuit personalization member is integrated in the print head 52 itself. The print head thus comprises, in addition to a conventional ink jet nozzle 55, a reader RD8 and an antenna coil AC8 connected to the reader. The reader RD8 is here in the form of a semiconductor chip fixed on one side of the print head, and the antenna coil AC8 is wound around the print head so that the magnetic field it emits is oriented towards the receiving plate 54. Part of the scroll mechanism is also shown in Figure 5. There are two rotating rollers 56, 57 vis-à-vis, at least one is motorized. The rollers 56 and 57 drive the sheet of paper 1 towards the receiving tray 54. Thus, the coil AC8 can be positioned at any point of the sheet 1 by controlling the movements of the print head 52. In this case, the IFile2 print file includes HALT (T) stop commands corresponding to areas being printed next to each integrated circuit to be customized. In the case where the data is written without printing the sheet (two-pass customization) the IFile2 print file contains only print head movement commands, paper scroll commands, and print order commands. Stop scrolling and stop the print head. This embodiment of the printer makes it possible to limit the number of readers RDi and offers a print head with two functions - printing on the one hand and writing of data without contact on the other hand - while

  using the drive means of the print head already available. However, it can be combined with the embodiment shown in FIG. 2. In this case the printer comprises both the fixed coils AC1-AC7 and the moving coil AC8. The RD8 reader can also be arranged at a fixed point of the printer. In this case, an antenna signal provided by the reader RD8 is fed to the antenna coil AC8 via sliding contacts or a flexible wire sheet capable of following the movements of the print head. Also, a movable member provided specifically for receiving the antenna coil AC8 may be provided. Such a movable member is for example slidably mounted on a separate guide rail of the rail 53. Figure 6 is a top view of another embodiment of a printer embodying the invention. The illustrated printer differs from that of FIG. 4 in that it comprises an RD9 reader connected to a large diameter antenna coil AC9 which extends below or below the receiving tray 54 and whose range (communication field) covers all or part of the paper scroll path or at least the receiving tray 54.

  In this embodiment, a contactless integrated circuit present in a sheet being printed is immersed in the magnetic field emitted by the antenna coil AC9 during all or part of the printing process and can therefore be customized without interrupt the scrolling of the paper. Several non-contact ICs can also be written sequentially using the AC9 antenna coil, if they are equipped with an anti-collision function. In this case, the RD9 drive issues anti-collision commands at the beginning of printing, lists

  the integrated circuits present in its field of communication, then selects them one after another to write the customization data. If the receiving tray 54 is suitably covered by the communication field of the antenna coil AC9, it is not necessary for the ATDR customization driver to stop the printing process or to request the print processor 58 to slow down. the printing speed. Indeed, even though the integrated circuits can not all be written during the printing process, the writing of the personalization data can continue after printing, when the sheet 1 is immobilized on the receiving tray 54. The figure 7 shows an example of a contactless integrated circuit structure 4 that can be incorporated in a printable medium, and FIG. 8 represents an example of a reader structure RDi applicable to the readers RD1-RD9 previously described. The integrated circuit 4 comprises an antenna circuit ACT1, a retromodulation switch SWm (for example a switch transistor), a modulation circuit MCT, a demodulation circuit DMCT, a central unit UC and a memory MEM1. Since the integrated circuit is preferably a low-cost component, the central unit is preferably a wired logic state machine rather than a microprocessor, capable of executing basic commands (write / read). The antenna circuit ACT1 comprises the antenna coil 5 previously described and a tuning capacitor Ca making it possible to tune the antenna circuit in the vicinity of a working frequency Fc, for example 13.56 MHz. The capacitance Ca is generally integrated on the semiconductor substrate of the integrated circuit while the antenna coil 5 is an external element connected to the semiconductor chip (external coil or "con on" type).

  chip ", as indicated above) .The integrated circuit is designed to operate in the presence of a magnetic field FLD of frequency Fc, emitted here by one of the antenna coils ACi of the printer In the presence of the magnetic field an alternating antenna signal Bag of frequency Fc appears in the antenna circuit The memory MEM1 comprises an electrically erasable and electrically programmable non-volatile memory zone, for example of the Flash or EEPROM type, and a volatile memory zone, for example RAM type, it can receive one or more programs or applications as well as application data or parameters.These data or programs can be written at the time of the customization of the integrated circuit The central processing unit UC provides outgoing data DTx to the circuit MCT which applies to a control terminal of the switch SWm, for example the gate of the MOS transistor, a signal SDTx carrying data DTx.The switch SWm is connected to the 5 of the antenna circuit 5 and its closing (on state) causes the appearance in the antenna circuit of a feedback signal (load modulation signal) at the rate of the signal SDTx. The integrated circuit 4 also comprises a diode or a diode bridge Pd ensuring the rectification of the antenna signal Bag and the supply of a supply voltage Vcc in the presence of the magnetic field. The diode bridge has an input connected to the terminals of the antenna circuit 5 and its output is connected to a smoothing capacitor Cs which supplies the voltage Vcc.

  The reader RDi shown in FIG. 8 comprises an antenna circuit ACT2, a generator FGEN including an oscillator, an RFM modulation circuit, an RFD demodulation circuit, an NFCC controller (microprocessor or microcontroller) equipped with a UART port ( not shown), a memory MEM2 comprising non-memory areas

  volatile and volatile areas. The antenna circuit ACT2 comprises an antenna coil ACi connected to terminals of the RFM modulator and the RFD demodulator, and at least one capacitor C1 for tuning the antenna circuit to the working frequency Fc. The antenna circuit may include various other tuning components as well as EMI filtering components (electromagnetic radiation filtering) represented as an EMI block. The generator FGEN provides a signal S1 (Fc) for excitation of the antenna circuit ACT2. The RFM modulator receives from the controller NFCC data to be transmitted DTx and applies the excitation signal Sl (Fc) to the antenna circuit ACT2 by modulating its amplitude according to the data to be transmitted. The excitation signal shows an alternating voltage Vac across the antenna coil and causes the emission of the magnetic field FLD (Fc). The amplitude of the voltage Vac and that of the magnetic field are thus modulated by the RFM circuit according to the data to be transmitted. The RFD demodulator circuit is connected to the antenna circuit ACT2 and receives the voltage Vac via a low-pass filter LFF which suppresses the carrier Fc. The RFD circuit thus receives a retromodulation signal from which it extracts DTr data (data transmitted by a contactless integrated circuit 4). It will be clear to those skilled in the art that the present invention is capable of various other variants, in particular with regard to: the management of the printing process, the management of temporary stops of the printing process (where necessary), or the slowing down of the printing process, - the arrangement of RDi readers and antenna coils ACi in the printer, - the number of antenna coils provided, and

  the extent of the communication field conferred on each antenna coil, which depends on the size of the antenna coil but also on the intensity of the excitation signal applied to it.

  FIG. 9 diagrammatically represents an embodiment in which a reader RD10 controls a plurality of antenna coils AC1 to AC7 arranged at different points of a printer, for example the same locations as those shown in FIG. the two terminals of each antenna coil AC1-AC7 to the reader RD10 is provided by low-loss switches PG1, PG2 of the "passgate" type (switches comprising PMOS and NMOS transistors). Each switch PG1, PG2 has an N-type input controlled by a selection signal SEL1 to SEL7 transmitted by the reader RD10, and a P-type input receiving the inverted selection signal provided by an inverting gate INV. Thus, the RD10 reader can connect to either of the antenna coils to communicate with a contactless integrated circuit in the communication field of the selected antenna coil. As before, the location of the RD10 reader may be distinct from the location of the antenna coils, which make it possible to communicate with the integrated circuits. Thus, in one embodiment of the invention, the printer could comprise only one or more antenna coils, and one or more connectors for connecting the antenna coil or coils to an external module comprising one or more readers. In this case, the provision of the antenna signal, the modulation of the antenna signal for sending data, the amplitude demodulation and the retrieval of data received by retromodulation are provided by the external module.

  The concept of the invention is also not reserved for inkjet printers and is applicable to various other types of printers, including laser printers.

  Finally, the present invention is also applicable to the customization of electrically coupled integrated circuits using dipole UHF antennas in place of previously described antenna coils. Such UHF integrated circuits can be passive and be powered by an ambient electric field. They also send data by back modulation, the UHF retromodulation consisting of a modulation of the reflectance coefficient of their antenna (technique called "backscattering"). In this case, the RDi players previously described are replaced by UHF readers suitable for writing data in this type of contactless integrated circuit.

Claims (29)

  A paper printing device comprising a paper scroll path (51-54), characterized in that it comprises at least one antenna (AC1-AC9) having a range covering all or part of the scroll path and allowing to write data in a contactless integrated circuit (4).   2. Printing device according to claim 1, comprising a plurality of antennas (AC1-AC7) each disposed facing a portion of the scroll path.   The printing device according to claim 2, wherein each antenna (AC1-AC7) has a communication field of limited range less than the extent of the scroll path and not covering the communication field of the other antennas.   The printing device according to claim 1, comprising an antenna (AC9) having an extended communication field covering all or part of the paper scroll path.   The printing device according to one of claims 1 or 4, comprising an antenna (AC9) having a communication field covering a paper receiving tray (54).   6. Printing device according to claim 1, comprising an antenna (AC8) integral with a movable member (52) of the printing device.   The printing device according to claim 6, wherein the movable member is a print head (52).   The printing device according to one of claims 1 to 7, wherein the antenna is an antenna coil configured to emit a magnetic field.   9. Printing device according to one of claims 1 to 8, comprising at least one reader (RDi, RD1-RD10) non-contact integrated circuit (4) electrically connected to at least one antenna.   Printing device according to one of claims 1 to 8, comprising at least one non-contact integrated circuit reader (RD10) (4) connected to at least two antennas (AC1-AC7) via switches (PG1, PG2).   A printing system comprising: - a printing device according to one of claims 1 to 10, and - a programmable device (8) configured to supply the printing device with data to be written in at least one circuit integrated without contact (4).   The printing system according to claim 11, wherein the programmable device (8) is configured to send to the printing device commands (HALT (t)) for stopping the drive of a sheet (1). ) in the scroll path, to provide pauses of sufficient duration to write data in a contactless integrated circuit embedded in the sheet. 35   The printing system according to claim 11, wherein the programmable device is configured to send to the printing device a print file (IFilel) including commands (HALT (t)) for stopping the training of the printer. a sheet (1) in the scroll path, to provide pauses of sufficient duration to write data in a contactless integrated circuit embedded in the sheet.   14. Printing system according to one of claims 11 to 13, wherein the programmable device is configured to detect in real time the presence of a contactless integrated circuit in a sheet (1) moving in the path of scrolling of paper.   The printing system according to one of claims 11 to 14, wherein the programmable device is configured to order the movement of a sheet (1) in the unprinted scroll path of the sheet, in order to write data in at least one contactless integrated circuit (4) embedded in the sheet.   The printing system according to one of claims 11 to 15, wherein the programmable device is configured to transmit anti-collision commands via the antenna (AC9), in order to write data in several integrated circuits. contactless in the communication field of the antenna.   17. A method of writing data in a contactless integrated circuit (4) embedded in a sheet (1), characterized in that it comprises the steps of: - providing a paper printing device comprising a path of scrolling paper (51-54), arranging in the printing device at least one antenna (AC1-AC9) having a range covering all or part of the scrolling path, arranging the sheet (1) in the scrolling path , and - use the antenna (AC1-AC9) to write the data 10 in the integrated circuit.   18. The method of claim 17 including a step of providing a plurality of antennas (AC1-AC7) each disposed facing a portion of the scroll path.   19. The method of claim 18, wherein each antenna (AC1-AC7) has a communication field of limited range less than the extent of the scroll path and not covering the communication field of the other antennas.   20. The method of claim 17 including a step of providing an antenna (AC9) having an extended communication field covering all or part of the scroll path.   The method of one of claims 17 or 20, comprising the steps of: providing an antenna (AC9) having a communication field covering a paper receiving tray (54); writing data into the circuit integrated without contact (4) during scrolling of the sheet or after scrolling of the sheet, when the sheet is immobilized on the receiving tray.   22. The method of claim 17, comprising a step of providing an antenna (AC8) integral with a movable member (52) of the printing device.   23. The method of claim 22, wherein the movable member is a print head (52).   24. The method according to one of claims 17 to 23, comprising the steps of: immobilizing the sheet in the scrolling path, and writing data in the contactless integrated circuit while the sheet is immobilized.   25. The method according to one of claims 17 to 24, comprising the steps of: sending to the printing device a print file (IFilel) comprising commands (HALT (t)) for stopping the driving the sheet in the scrolling path, and - writing data in the contactless integrated circuit 25 while the sheet is immobilized.   26. A method according to one of claims 17 to 25, comprising a step of detecting in real time the presence of the non-contact IC in the sheet during movement of the sheet in the scroll path.   The method according to one of claims 17 to 26, comprising a step of using a magnetic field emitting antenna coil to write data in a contactless integrated circuit.   28. The method as claimed in one of claims 17 to 27, comprising the steps of: providing at least two antennas (AC1-AC7), and alternately connecting the antennas to a reader (RD10) ) of integrated circuit without contact, via switches (PG1, PG2). 10   29. The method according to one of claims 17 to 28, comprising the steps of: - issuing anti-collision commands via the antenna (AC9) displacement, and - writing data in several non-contact integrated circuits found in the communication field of the antenna.