WO2005124656A1 - High-speed communication method and system with electric contacts - Google Patents

Abstract

The invention concerns a high-speed communication method between an integrated circuit chip (5) and at least one terminal (2), the chip comprising a communication and power supply interface with contacts (3). The invention is characterized in that it comprises the following steps: modulating a contact communication in accordance with a non-contact high-speed modulation standard (ISO, 14443); high-speed contact communication using two contacts (C4, C8) of the contact interface (3); controlling reception; transmitting the ISO 14443 high-speed contact communication using a universal block (UART) (5a) integrated in the chip and operating in accordance with the ISO 14443 standard of non-contact high-speed modulation (20). The invention also concerns high-speed communication systems and devices.

Description

 HIGH-THROUGHPUT COMMUNICATION SYSTEM AND METHOD

1 / invention relates to a high speed communication method and system with electrical contacts between an electronic circuit and a terminal. It also relates to a communication method and system with dual interface, contacts and without electrical contact, between an electronic circuit and at least one terminal. The electronic circuits include or use a communication and supply interface of the contact type and / or without electrical contact, in particular in an intelligent portable object. Intelligent portable objects are for example smart cards, electronic tickets, so-called "dongle" cards or other modules such as those for proximity communication (eg „: NFC) or semi-proximity (eg: BlueTooth); Any electronic circuit having a communication function, or even a chip having an antenna engraved or integrated on the chip. This includes any object having a communication interface with galvanic contact and / or antenna. Intelligent portable objects with dual interface, contact and contactless are sometimes called "CombiCard" or object with dual interface. They have means allowing communication via a galvanic or ohmic interface called "in contact" with one or more Electronic data transmission terminals and / or other remote portable objects In addition, they also include means allowing remote communication via a contactless interface. These objects may be subject to the following structural and / or operating standards: ISO.7816 prescribing a contact communication interface; and in particular a limited data communication speed of around 300

K.Bits per second. - ISO.IEC14443 prescribing a contactless communication interface, in particular the chapter

611 (response time known as "FDT"). - 3GPPTS11.11 relative to so-called objects

"SIM" or similar, to be inserted in a terminal, in particular chapter 43 (galvanic communication interface). In addition, objects may conform to other communication specifications, such as proximity such as ECMA340 called "NFC" or semi-proximity such as "BlueTooth" and other broadband communications called "iFi". The maximum bit rates prescribed by the ISO.IEC14443 standard are of the order of 847 K. Bits per second. Upcoming developments are targeting speeds of the order of 6 M.bits per second and then speeds of the order of 10 to more than 25 M.Bits per second. These are the speeds beyond those permitted by ISO.7816, for example 400 K Bits / s and preferably flows greater than or equal to approximately 847 KBits / s which is designated by "broadband" in the remainder of the document. Among the current "CombiCard" objects capable of meeting the ISO.7816 standard and a "contactless" standard, let us mention those which have chips: Infineon SLE 66CLX320P; Philips P5CT072 STMicroElectronics ST19XR34. The "combi" objects have been proposed in the form of double modules or double chips each having their function and independent communication interface. The invention also relates to any type of terminal, in particular mobile telephone terminals (eg: GSM, 3GPP; UMTS; CDMA; Etc.), computers, portable personal assistants (eg: PDA), decoding box, etc. They can be secured by at least one smart portable object. The following documents describe a teaching useful for the implementation of the invention and the corresponding passages below form part of the description. The document FR 2783336 describes a smart card provided with a chip connected to contact pads of a galvanic terminal block. The third and fourth contact pads of the chip constitute a differential pair and are capable of ensuring high speed data transmission, in particular USB. The document FR 2686997 proposes a smart card which may have only two contacts used for both to exchange information

(instructions and data) between the card and a card reader, and to a power supply to the card. According to the invention, the contacts are preferably a clock contact (CLK) used for the synchronization of data and instructions, and a data input / output contact (I / O) used for the transmission of data and instructions. from the reader to the card and to data transmission from the card to the reader. For power supply, a full wave rectifier (diode bridge) can be placed between the two contacts. It also relates to the communication protocol which makes it possible to use only two contacts while having instructions similar to those of conventional smart cards (initialization of the card, incrementation of address of memory cell, reading of the cell, writing , comparison of a confidential code). However, the communication speed of which a portable object of the prior art is capable is far from reaching the speeds observed in the networks of terminals or other local links between these terminals. The speeds with the following networks are: - GPRS: at most 750 K. Bits per second; - UMTS: 2 M. Bits per second; - WiFi (IEEE802.X): 10 - 100 M. Bits per second. Regarding examples of local connections between terminals, the speeds observed are: - USB1.1: 12 M.Bits per second; - USB2.0: 400 M.Bits per second; - BlueTooth: 1 M. Bits per second; - FireWire: 400 - 800 M.Bits per second; - MMC.SPI: 5 - 20 M.Bits per second. In comparison, according to the ISO.7816 standard and with a conventional protocol T = 0 to 5 MHz and 16 clock pulses per unit of elementary time (called "ETU" for English "Elementary Time Unit"), the bit rate is currently around 300 K. Bits per second. At best, with 8 clock pulses per second, we can consider reaching a speed of 625 K. Bits per second. In this regard, in conventional protocol T = 0, the ratio between gross and net bandwidth is 1.5; while at present, cell phone terminals have a clock frequency dedicated to a portable object, less than 5 MHz. In addition, in certain cases, it may be necessary for the object to process at least two concurrent transactions (eg: Payment, identity, telephony, access), each coming from a different source and conforming to its own communication protocol. , without the processing of one causing the irremediable cessation of processing of the other. It may also be necessary to have secure access to information services, for example multimedia (films, music, cartography, etc.). For example, it would be interesting to be able to perform data encryption operations to protect, on the fly or to allow the rapid loading of heavy files within a portable object: for example information products (music, images, etc.) or biometric data of a carrier of the object; In the latter example, the rapid transfer would authorize an electronic identification operation on the fly, within an acceptable period, in particular during customs clearance or access to a protected place. But at present, proposals for integration by a portable object, of a broadband protocol have always implied both on the side of this object and of the terminal, the addition of additional means such as the USB protocol and therefore considerable investments. Although some founders of chips for portable objects have been offering chips for years that integrate means of reception and processing of data conforming to a universal serial bus protocol known as "USB", there are at present on the market for objects and terminals of this type, due to the importance of the modifications and investments to be undertaken. On the other hand, the world of intelligent portable objects should be opened up to proximity communications (eg: NFC). The invention aims to overcome these drawbacks, and achieve the goals below. The main objective of the invention is to increase the speed of communication

(compared to the speed prescribed by ISO 7816) between a terminal and an electronic circuit having a contact interface. Another objective is to allow high-speed contact and contactless communication with more economical means. To this end, the invention relates to a high-speed communication method between an integrated circuit chip and at least one terminal, the chip comprising a communication and power supply interface with contacts. It is distinguished in that it comprises the steps: - of modulating a contact communication according to a high-speed contactless modulation standard, - of communication with high-speed contacts using two contacts of the contact interface, - reception control - transmission of high-speed contact communication using a universal block (UART) integrated in the chip and operating according to the high-speed contactless modulation standard. According to one characteristic, the high-speed contactless modulation standard is ISO 14443. According to another characteristic, the chip is further provided with contactless type communication and supply means, comprising an antenna interface and operating according to said high-speed contactless modulation standard, and the method comprises a step according to which the universal block (UART) is assigned to one or the other high-speed communication using chip processing means. According to another characteristic, to manage or allocate the use of the universal block (UART) (simultaneously) to one or the other high-speed communication, the presence of activity on one of the interfaces is detected high-speed communication, - the processing unit is informed of this activity, if necessary, in response to this activity information, a management unit management program re-affects the use of the universal block for the benefit of one of the broadband communications. Thus, the principle of the invention consists in transposing a communication protocol known from the contactless domain and generally fairly rapid and evolving, to an electronic circuit of the contact domain and usually operating with a contact type protocol not fast enough and not very scalable. In addition, the high-speed "combi" function is achieved economically by the use of a common UART since operating on compatible or identical protocols. Management is carried out by a processor according to a management program and a parameter detection circuit signaling the operation of one of the interfaces. The invention also relates to a high-speed communication system comprising a portable object with integrated circuit chip and at least one terminal, the object comprising a communication and power supply interface with contacts. It is distinguished in that the terminal and

1 obj and include: means for modulating contact communication according to a high-speed contactless modulation standard, - a communication interface circuit operating with two electrical contacts. - reception control means - transmission of the communication with high-speed contacts comprising a universal block (UART) integrated in the chip and operating according to a high-speed contactless modulation standard. According to one characteristic, the portable object comprises means of communication and supply of the contactless type, operates according to said high-speed contactless modulation standard, uses the same universal block (UART), and the processing means are capable of manage the use of the universal block (UART) for one or the other broadband communication according to predetermined criteria. The invention is now described in detail with the aid of exemplary embodiments which refer to the figures below. - Figure 1 is a diagram illustrating the basic communication system of the invention; - Figure 2 is a schematic view of a use of the invention in the context of several communications; Figure 3 is a schematic view illustrating the electrical structure of the terminal and the portable object of Figure 2; - Figure 4 is a diagram of the software operating principle of the portable object; - Figure 5 illustrate an example of steps of the method of the invention implemented in application of the operating principle of Figure 5; - Figures 5a, 5b, 5c illustrate witness registers of communication activities. - Figure 6 illustrates a priority table for the management of different communications. - Figure 7 illustrates a more detailed electrical diagram of the microcontroller of the portable object of Figure 3. In Figure 1, the broadband communication system of the invention comprises an intelligent portable object 1 and at least one terminal 2 in communication relation via a contact interface 3. The object is said to be intelligent in so far as it integrates a logic processing unit. Object 1 in the example is a smart card, in this case a multi-application card. It comprises a card body 4 and a module provided with an electronic circuit 5 such as an integrated circuit chip or equivalent; The communication and power supply interface with contacts 3 is in particular for convenience in the form of a smart card type terminal block; but not all terminal block contacts are necessarily used for high speed communication. The object can also be an electronic communication device consisting for example of an electronic ticket, a so-called "dongle" card or other device, in particular proximity (eg NFC) or semi-proximity (eg BlueTooth) communication. The electronic chip 5 of the subscriber identification card comprises, in known manner, a processor (CPU 21) connected on the one hand via a data and control bus to memories 24, in particular a program memory ROM comprising in particular a system operating system (OS) and specific algorithms, and on the other hand a programmable memory and a RAM. The programmable memory, in particular of the EEPROM type, can comprise user data, in particular subscriber or data relating to his subscription with an associated encryption key to authorize a communication service and / or specific applications.

The processor manages in particular at least one interface circuit with contacts 3 as well as the data of the various communications. According to the invention, the communication interface requires at least two electrical contacts 4 (ranges C4, C6) connected to two connectors of a high speed communication port (ECP) of the terminal. In addition, the terminal and the intelligent object each comprise means for modulating the communication to allow modulation in accordance with a contactless modulation standard; they also include means of transmission / reception via the two contacts. Contactless communication is said to be broadband by comparison with known contact communication in accordance with ISO 7816. Each of the communication devices, card and terminal, must also integrate reception control means - transmission of high communication -debit. These control means include a universal block (UART 5a) whose operation conforms or (similar) to a high-speed contactless modulation standard. Preferably, this standard is ISO 14443, reserved in principle for contactless communications, but in the invention, it is used for high-speed communication with contacts. Thus, thanks to the use of a communication protocol in the contactless technical field, the terminal and the card form a (basic) communication system with two high speed electrical contacts. In the context of an optional more complete use, the basic system of FIG. 1 may further include contactless type communication and supply means for radio frequency type 7 communication (eg: RF; NFC; BlueTooth These means of communication can be distributed indifferently in the terminal and / or in the card body and / or the module and / or the integrated circuit chip. In the example, these means are preferably in the card and comprise an interface circuit comprising an antenna interface 6. According to a characteristic of the invention, these means operate according to the same high-speed contactless modulation standard previously used for the basic contact system; in particular standard 14443 commonly used for contactless. In Figure 2, the system optionally includes an additional terminal 2a which can be connected to other terminals 2b (of the same type or different) via any other communication network, in particular to a mobile telephone network 8 (eg: GSM; 3GPP; UMTS; CDMA). In a particular case, the terminal can be designed to allow several types of communication with the object and itself, such as contact and contactless communications. The contactless communication 7 uses an electromagnetic field conveying a signal modulated in accordance with the ISO standard. IEE.14443. The electromagnetic field carries clock, electrical power and data resources. The invention is economical in design because it uses the same UART (5a) for high-speed contact or contactless communication as will be seen later. As a result, the microcontroller of the integrated circuit 5 is able to perform management of the universal block (5a): UART 14443, for the benefit of one or the other high-speed contact or contactless communication. This management is carried out in application of the predetermined principles, programs and criteria as illustrated in FIGS. 4, 5, 6. These programs and data are loaded into a non-volatile memory, for example of the Eprom type. They can be, if necessary, entered or programmed by the user. In the context of an even more complete use of the invention illustrated more particularly in FIG. 7, the intelligent object may also include means of communication and supply with the host terminal according to the ISO 7816 standard and in particular a 3 to 8 contact interface with contact pads in accordance with a contact distribution table presented below. Consequently, the chip contains another universal block 18 for reception - transmission, dedicated for its part to the ISO 7816 standard; This block 18 is connected to the area C7 of the galvanic terminal block, via a contact pad of the chip 5. A wiring connects a contact pad of the chip 5 to the area C1. Cabling connects another pad of chip 5 to range C5. These cables allow in particular a supply to the object 1 of electrical power resources operated via the contact interface 3. The invention thus conceived allows the transmission / reception, within the chip, of ISO 7816 frames intended for UART ISO 7816 and / or broadband, to the universal UART block dedicated to ISO.IEC 14443; The method of the invention can implement the following steps. In the case of a high-speed frame, an extraction phase is carried out from this high-speed frame, of a portion of data then processed asynchronously according to the protocol (T = CL) by the chip (5 ); on the other hand a clock signal and initialization of the chip (5); While the electrical power is extracted from the contact interface (Cl; C4) (3) as for a power supply according to ISO.7816 standard. The terminal block of the card is defined by standards. He has here for three types of communication envisaged eight contact pads (figure 3) Cl to C8. According to for example the standard 3GPPTS11.11 (431), the ranges C4 and C8 were not used in the operation of a conventional terminal 2 of cellular telephony called "GSM". According to the standards, the areas C4 and C8 are each connected to a port on the chip 5. On the other hand, it is noted in the example of FIG. 3 that the antenna 3 is connected to these areas C4 and C8, and integrated into the body 4. The data signals passing through the contact pads C2 and C7 in particular are digital signals called "digital" of binary type. According to the ISO 7616 standard to which the interface 3 is dedicated, these signals are asynchronous with a protocol T = l or T = 0. While the data signals in particular which pass through the areas C4 and C8 or directly transmitted to the chip 5, are modulated signals (radio frequency for example), coming from the antenna 3. According to the ISO standard. IEE.14443 to which the interface 3 is dedicated, these signals are asynchronous with a T = CL protocol. For the realization of FIG. 3, we have the definitions and functions of the ranges C1 to C8:

A conventional contactless frame has an amplitude greater than 5V; while a High-speed (HD) frame has a conventional amplitude of 1.8V, 3.3V or 5V (in accordance with ETSI TS 102 221 V6.4.0 (2004-03)). Referring now to the electrical circuit of FIG. 3 or FIG. 7, the UART 14443 (5a) is connected in parallel for the two RF and high-speed (ECP) circuits. To these terminals, areas C4 / C6 for the ECP circuit are connected respectively using connections 12, 13 and areas C4 (LA) / C8 (LB) using connections 12, 14 for the RF circuit Each circuit includes an activity detector connected in parallel respectively to the terminals corresponding to ranges C4 / C6 or C4 (LA) / C8 (LB). The RF circuit comprises two capacitors in parallel F1, F2 whose use is switchable using a first logic flip-flop 15. The ECP and RF circuits are switchable in particular at C8 / LB and C6 / LB 'at l 'help a second logic flip-flop 16. Toggle switches 15 and 16 can be coupled together. The universal block 5a of the chip is connected so as to receive the differential signal from C4 / C6 or C4 (LA) / C8 (LB) of a high-speed communication according to the communication selected by the processing unit. The UART (5a) receives at one of its terminals two ECP and RF circuits. When the switches are switched to position A (Figure 3), the RF circuit is closed and ECP open: that is, only the activity present in C4 / C8 (RF channel) is transmitted and processed by the UART 5a . In this configuration, an optimum tuning capacity of the RF circuit is used. Concerning the activity present on the port

ECP is applied to the ECP detection device only. When the 2 switches are switched to position B, the RF circuit is open and the ECP circuit is closed: i.e. the activity present in C4 / C6 (ECP channel) is transmitted to UART 14443 and the activity on the RF channel remains applied to the RF detection circuit; the level of this activity undergoes an attenuation factor due to the replacement of the optimal tuning capacity RF by a partial tuning capacity F2. The way in which the chip 5 operates the specific management of the clock signal, power supply and data management and processing, can be carried out in accordance with patent applications: FR0351089; FR0351090; FR0351091 and FR0351092 of

December 17, 2003. In RF radio frequency mode, the power supply is taken from the radio frequency field, while in contact mode (ECP / ISO 7816), the power supply is drawn from the contact power supply while respecting the consumption constraints of the contact mode. (GSM / 3G / standby mode ..). In the example, the power management of the chip is carried out in the following manner. When the communication must pass from a contact communication (high speed ECP / ISO 7816 classic) to a contactless RF communication, the processor switches between the two types of supply by any known means. The chip also includes means associated with RF activity detectors, ECP making it possible to inform the processing unit of any activity on one of the communication channels (any means known to those skilled in the art to convert - for example - voltage information in a raised flag in a register). In particular, the RF detectors can each make an analog / logic circuit able to trigger the writing of a value or a flag in an appropriate register or memory space usable by the microcontroller. Regarding a possible ISO 7816 standard communication, conventional means exist already (interrupt / flag) to inform the processor of an activity on this port (fig. 7). Thus, according to one embodiment of the invention, the ISO 7816 interface, the ECP interface and the ISO 14443 contactless interface can be managed by the microcontroller. Figures 4, 5, 6 respectively illustrate a principle and program for managing the use of UART 5a as well as data in a table 11 representing use criteria 17, concurrent uses of UART or any other competing resource of the microcontroller. This table defines for each communication which has priority over the other or the others according to criteria or events 17, various such as "permanent, temporal, according to an identifier" ID "of the transaction arriving or in progress (transport ID, payment ID , Download ID, aircraft ID, duration of an announced transaction, etc.) These data governing the priority of communications are preferably accessible and programmable by the user. The operation of the communication system of the invention is described below. -after in connection with Figures 4, 5, 6, 7. The method of one invention can operate with the two contacts of the contact interface of the card and the terminal connector to perform high-speed ECP communication at contact; the communication is modulated according to a high-speed contactless modulation standard, preferably ISO 14443 However, when the system also has RF contactless type communication and supply means described above, the method implements steps for managing these communications and / or the use of shared resources or components. In particular, the microcontroller manages the allocation of the common universal block (UART) to one or the other high-speed ECP / RF communication. When a communication is initiated and another communication can be initiated on the other channel, it is important to report it to the processor. An interruption of the processing unit is then caused using the interrupt controller 22 (fig.7); this processing unit is then free to give the appropriate action. It is also necessary to ensure that the level of the communication to come is low enough not to disturb the current one. To this end, in FIG. 3, the capacitors Fl & F2 are chosen in such a way that the contactless RF interface is granted when the contactless mode is chosen (Fl in a circuit RL1F1) and strongly detuned (F2 in a circuit RL1F2) when the ECP mode is selected. RF or ECP detectors can report activity on their channel to the microcontroller respective and cause a task interruption to the microcontroller. The tasks indicated in 18, 19 (saving the context, storing a detection flag, restoring the context) are then executed. How the proven presence of activity on one of the communication ports is handled depends on the operating system (OS). The operating system can, for example, simply raise a flag 23 in the routine for interrupting the detector. This flag will be used later when the operating system is able to process said communication. This interruption can also lead the operating system to treat this channel with absolute priority, going so far as to abandon any other task in progress. Other possibilities can be offered to the operating system and the choice depends on the options taken at design time. According to a characteristic of the invention, each RF and FD detector has its own interrupt vector; On the other hand, if this vector were to be unique, we could provide another means of differentiation of the 2 RF and ECP activities (for example an identification flag raising:

1 bit in a register) In the example (fig. 4), the microcontroller program conventionally includes a task sequencer or a simple command interpretation loop 20. The microcontroller is notified by consulting the activity flags of an ECP or RF communication on hold (20). When the system is ready to switch to one of tasks 21 or 22 (RF or ECP), the task sequencer connects the microcontroller to this task, suspends or aborts the current context, closes the current port if necessary, opens the new port of ECP or RF communication and activates the associated context. A use of the invention is described below in the context of a transport network with reference to FIG. 5. The program begins at step 100 with as starting status an absence of communication in progress ECP or RF, as indicated by zero values in the communication activity witness registers of Figure 5a. The system is for example in communication using the ISO 7816 port within the framework of an operator network authentication and if necessary, this activated can be signaled in an equivalent manner using another register (not shown). . The flip-flops 15, 16 are in position as in FIG. 3: circuit of the ECP channel open and circuit of the standby RF channel closed. To access a transport network, figure 2, the user approaches his terminal with an access point 2a (contactless terminal) which generates a electromagnetic field and which is able to obtain a right of access or an identification of a transport ticket. In step 110, this electromagnetic field is detected by the RF detector included in the RF circuit of the card. In response, an analog / logic circuit of the microcontroller associated with the activity detector generates an interruption of the processing in progress in order to record (raising of a flag) the presence of an RF communication on this port. The flag is consulted in the command interpretation loop (or task sequencer) and causes the program of the processing unit to be rerouted according to the diagram in FIG. 4, in particular in order to resolve the priority conflicts on the ports of communication. The program then plugs into a test

120 consisting in determining whether there is another communication in progress in particular by reading the zero value of the register / ECP indicator (fig. 5a) In the absence of other concurrent communication, the program branches to a step

130 for activation / opening of the RF communication channel. At the same time or beforehand, the RF witness register takes the value 1 and the RF communication is established in step 140. Step 150 marks the end of the detected RF communication, for example by receiving an end information communication or by a absence of electromagnetic field signaled by the RF detector. The program places an end of communication flag (and / or a zero value in the witness register) (configuration of FIG. 5a again) and switches flip-flop 15 to put the RF circuit on standby. Otherwise, concurrent ECP communication in progress (branch yes) in step 120, the program branches to the second test 160, according to which the procedure to be followed is determined in relation to predetermined data. For this, the program will consult criteria, data personalized in the factory in a memory or having been the subject of a prior selection / programming of priority of a user according to his needs. The table in Figure 6 illustrates examples of criteria. Thus, the line entitled "permanent" with the values 0 in the ECP / RF columns, indicates that there is no permanent priority

(or by default) from one channel to another. The 8h-9h time criterion line indicates priority to the RF channel during this time slot; it may represent a user need for daily access to the metro at these times. Other criteria such as transport ID

(airplane), payment ID, loading ID represent an RF priority if an identifier relating to a terminal or terminal is detected electromagnetic access to a transport network or a payment terminal ... The criterion can also be the time announced by a terminal necessary for a transaction, for example less than 1 hundredth of a second (information may be contained in a message preliminary or resulting for example from an authentication of the terminal). In the example, the user having a download in progress via the telephone network, (a value 1 would first be placed in a witness register), in addition, an identifier of the nature of the ECP communication in this case, a download is associated with the witness register. It follows from the table that the RF communication does not have priority and the program then connects to step 180 where the ECP channel is maintained; if necessary, the microcontroller sends out any signal informing of the unavailability of the RF channel (message on the screen, audio signal ...) and then the program ends. In the "yes" branch of test 160, RF communication has priority, for example because we are in the time slot 8 am to 9 am and the program therefore connects to step 170; At this stage, the microcontroller saves the context of the ECP communication and restores the data before the ECP communication, then suspends the ECP channel, sets an ECP inactivity flag and / or a value

"0" in the ECP witness register and a value of 1 in the RF witness register in Figure 5b. Then, the program connects as before to the communication step 140 proper and ends as before. The action of the microprocessor may not be determined by a step of testing a program but may be established by wired circuit or the like, for example one of the channels always has priority over the other. The assignment of a channel can also be done in the absence of communication in progress. In fact, it is possible to have three data streams received by the object 1: a stream conforming to the ISO.7816 standard, in particular via the range C7; a flow conforming to the ISO standard. IEC.14443, in particular via ranges C4 and C8; and a high-speed asynchronous flow, in particular via the ranges C4 and C6. It is possible with the object of the invention, for example to secure an application 7, the data of which passes through the contactless interface 3, simultaneously with a separate application, the data of which passes through the contact interface, or even of an application of secure high speed data transfer to object 1. These interfaces are connected to the same chip 5 within object 1, and communications or contactless and contact applications are processed on this same chip 5. Communication 8 can allow, for example, a secure purchase from terminal 2, and from a service server (not illustrated) which is itself connected to a cell phone terminal. This purchase is recorded in the form of values, in object 1. Similarly, communication 8 can allow secure access to information services, for example multimedia or perform encryption of data to be protected, on the fly or fast loading of large files within a portable object 1. In this example, rapid transfer authorizes an electronic identification operation on the fly, within an acceptable period. The invention provides solutions allowing a contact or contactless communication interface, within a portable object such as a smart card (banking, transport, telephony, identification or other) called

"Combi", to ensure: - high speed data transfers (for example from 847Kb / s to 10 or even 27Mb / s); - simultaneous data processing, without major modification of the universal reception - transmission blocks. The card's communication functions allowing broadband can equip any communication device with contacts, such as a terminal, reader, PDA, etc. In particular, the management of a common broadband UART can be ensured by processing means equivalent to those of the card. In the case of a reader or terminal for example, provision can be made to provide the devices with detectors of the nature of the communication which will be engaged (contact or contactless), in particular detector for presence of contact card, make it possible to communicate information to the processor so as to assign a shared UART to a high-speed ECP communication with contacts. The invention also relates to an integrated circuit chip comprising processing means capable of managing a communication with high-speed contacts. The universal block (UART) operates according to a high-speed contactless communication standard; the block (UART) can be assigned as well (for example shared) to contact or contactless communication by the processing means.

Claims

CLAIMS 1. A method of high-speed communication between an integrated circuit chip and at least one terminal, the chip comprising a communication and power supply interface with contacts, characterized in that it comprises the steps: - of modulation of a communication with contacts according to a high-speed contactless modulation standard, - communication with high-speed contacts using two contacts of the contact interface - reception control - transmission of high-speed communication with contacts using a universal block (UART) integrated in the chip and operating according to the high-speed contactless modulation standard. 2. Method according to claim 1, characterized in that the high-speed contactless modulation standard is standard ISO 14443. 3. Communication method according to one of claims 1 or 2, characterized in that it comprises steps according to which the chip is further equipped: - contactless type of communication and supply means comprising an antenna interface and operating according to said high speed contactless modulation standard, - the universal block (UART) is assigned to one or the other high-speed communication using chip processing means. 4. Communication method according to one of the preceding claims, characterized in that the chip also includes communication and supply means according to ISO 7816 standard, comprising a contact interface. 5. Method according to claim 4, characterized in that to affect the use of the universal block (UART) simultaneously to one or the other high-speed communication, it detects the presence of activity on the one of the high-speed communication interfaces, - the processing unit is informed of this activity, if necessary, in response to this activity information, a management unit management program reassigns the use of the universal block in favor of one of the broadband communications. 6. Method according to claim 4, characterized in that the contact interface is a contact module conforming to ISO 7816 comprising at least contact pads C4, C6, C8 and the pads C4, C6 are used for the communication with high-speed contacts - the ranges C4, C8, (LA, LB) are used to connect the contactless communication antenna, - the ranges C1 / C5 are used for the voltage supply, the universal block receives the differential signal from C4 / C6 or C4 (LA) / C8 (LB) of a high-speed communication according to the type of communication (RF or ECP) selected by the processing unit. 7. Method according to claim 6, characterized in that when the contact communication is selected, a frequency tuning circuit of the contactless communication means is detuned. 8. Method according to claim 6, characterized in that when the contactless communication is selected, the frequency tuning circuit is tuned. 9. Method according to claim 6, characterized in that to detune, a second frequency tuning circuit is selected so as to receive a contactless communication activity attenuated compared to the activity received with the first tuning circuit frequency granted. 10. High-speed communication system comprising a portable object with integrated circuit chip (5) and at least one terminal (2), the object comprising a communication and power supply interface with contacts (3), characterized in that that the terminal and the object comprise: means for modulating a contact communication according to a high-speed contactless modulation standard, a high speed communication interface circuit operating with two electrical contacts. - reception control means - transmission of the communication with high-speed contacts comprising a universal block (UART 5a) integrated in the chip and operating according to a high-speed contactless modulation standard. 11. System according to claim 10, characterized in that the high-speed contactless modulation standard is standard ISO 14443. 12. Communication system according to one of claims 10 or 11, characterized in that the portable object comprises: - contactless type communication and supply means comprising an antenna interface (6), operating according to said high-speed contactless modulation standard, and using the same universal block (UART 5a), - and in that that the processing means (21,

11) are capable of managing the use of the universal block (UART 5a) for one or the other high-speed communication, contact or contactless, according to predetermined criteria. 13. System according to one of claims 10 to 12, characterized in that the terminal is a mobile telephone terminal and the chip is a smart card chip. 14. System according to one of claims 12 to 13, characterized in that the chip comprises user programmable data (17) governing the priority of communications. 15. Electronic communication device comprising a communication and power supply interface with contacts, characterized in that it comprises: means for modulating a communication with contacts according to a high-speed contactless modulation standard, - an interface communication consisting of two electrical contacts. - reception control means - transmission of the communication with high-speed contacts comprising a universal block (UART) integrated in the chip and operating according to a high-speed contactless modulation standard. 16. Integrated circuit chip comprising processing means capable of managing a communication with high-speed contacts, characterized in that it comprises a universal block (UART) operating according to a communication standard without high-speed contact. 17. Chip according to claim 16, characterized in that the universal block (UART) is assigned to both contact or contactless communication by the processing means.