EP1695298A1

EP1695298A1 - Electronic package, in particular for an electronic payment terminal

Info

Publication number: EP1695298A1
Application number: EP04804909A
Authority: EP
Inventors: Jérôme SOUFFLET
Original assignee: Thales SA
Current assignee: Thales SA
Priority date: 2003-12-19
Filing date: 2004-12-17
Publication date: 2006-08-30
Also published as: WO2005066904A1; FR2864286B1; FR2864286A1

Abstract

The invention relates to electronic transactions, in particular for electronic payment carried out by means of a microprocessor card, also known as a chip card. Said invention also relates to an electronic package (1) for an electronic transaction device comprising at least one anti-intrusion unit describing a security area which is configured in such a way that it makes it possible to detect physical intrusions therein, a program store (6) arranged in the security area, wherein at least one secured software component for carrying out an electronic transaction is stored, a microprocessor (2) which is placed in the security area and connected to the program store for actuating the secured software component, a communications interface (4) which is connected to the microprocessor and used for connecting the microprocessor to a processing unit disposed outside said package in such a way that it is enabled to carry out data exchange with said microprocessor. The inventive electronic package can be used for carrying out banking functions by an electronic payment terminal and certified according to banking security standards independently from other material and/or software components of said electronic payment terminal.

Description

Electronic module especially for electronic payment terminal

The present invention belongs to the field of electronic transactions. It relates to an electronic module able to be used for example in an electronic payment device. An electronic payment device is a device for making electronic payments. Electronic payments are often made using a bank or credit card, such as a smart card (also known as a microprocessor card) or a magnetic stripe card. An electronic payment device generally comprises means for reading a smart card with or without contact, a microprocessor, a keyboard in particular for entering a confidential code, and a display screen. Electronic payment terminals (EPTs) are electronic payment devices that allow complete electronic payment until the printing of a ticket. There are simpler electronic payment devices, called confidential code entry boxes (known as "PIN-Pad" in Anglo-Saxon literature), which only allow authentication of the holder of a smart card. during an electronic payment. In any case, electronic payment devices are subject to banking security standards. Electronic payment devices must be certified by recognized organizations to demonstrate compliance with these banking security standards. A certification translates in practice by the allocation of serial numbers, a serial number being assigned to each hardware component and software component of the device. Examples include the EMV security standards defined by the financial institutions EUROPAY, MASTERCARD and VISA. A first certification, called "EMV Level 1", relates to communication with the smart card. A second certification, called "EMV Level 2", concerns the processing of applications. Each hardware or software evolution of an electronic payment device requires a new certification. The plaintiff posed the problem of accelerating the certification of payment devices electronic, when an evolution concerns insecure software components. A secure software component is a software component that processes confidential data. Indeed, an electronic payment application may include secure software components and non-secure software components. On the other hand, there are hybrid devices, making it possible to carry out not only electronic payments, but also tasks unrelated to electronic payment (electronic agenda, spreadsheet, word processing, etc.), the applications making it possible to perform these tasks. with no secure software components. We can quote for example the French patent application n ° 2 812744 filed on August 4, 2000 which describes examples of hybrid devices. A hybrid device can be trained by a personal electronic assistant (known by the acronym PDA in the English literature) equipped with a smart card reader, and used to make electronic payments. The invention makes it possible to accelerate the certification of electronic transaction devices when an evolution relates to insecure components. To this end, the subject of the invention is an electronic module able to be used in an electronic transaction device, the electronic module comprising at least: - an anti-intrusion device, delimiting a secure area, configured to detect physical intrusions in the secure area, „

- a program memory, in the secure area, in which is stored at least one secure software component of an electronic transaction application, - a microprocessor, in the secure area, connected to the program memory, intended to execute the component secure software,

- A communication interface connected to the microprocessor, the communication interface being intended to connect the microprocessor to a processing unit external to the module so as to exchange data with the microprocessor. According to an advantageous embodiment, the electronic transaction application further comprises a non-secure software component intended to operate in interaction by exchanging non-confidential data with the secure software component, said non-confidential data being exchanged via the interface communication, the non-secure software component being intended to be executed by the external processing unit. According to an advantageous embodiment, the module further comprises means for securing software, at the transport layer of the IP model, the communication link intended to be connected to the communication interface, so as to guarantee the confidentiality of the data exchanged on this link with the microprocessor. According to an advantageous embodiment, the electronic module further comprises a smart card interface, connected to the microprocessor so as to transmit requests from the microprocessor to a smart card and responses from the card to the microprocessor during the execution of the secure application. According to an advantageous embodiment, the program memory and the microprocessor are an integral part of a microcontroller. According to an advantageous embodiment, the electronic module further comprises at least one interface for a secure memory card, connected to the secure microcontroller, for storing secret information in a secure memory card. According to an advantageous embodiment, the electronic module further comprises means for authenticating a smart card holder (8, 9), connected to the secure microcontroller, the execution of the secure application implementing a method for authenticating a smart card holder, the authentication method using said means for authenticating a holder. According to an advantageous embodiment, the authentication means comprise input means, connected to the secure microcontroller, the input means being configured to receive secret information entered by the carrier. According to an advantageous embodiment, the authentication means further comprise display means, connected to the secure microcontroller, the display means being configured to allow the display of information for the wearer during activation. implementation of the authentication process. According to an advantageous embodiment, the display means are formed by a screen or a matrix of individually controllable light elements. According to an advantageous embodiment, the authentication means are biometric means making it possible to authenticate a carrier by comparison of physiological characteristics of the carrier with data stored in the chip card. According to an advantageous embodiment, the electronic module further comprises a magnetic stripe card interface, connected to the secure microcontroller, to allow the reading of a magnetic stripe card by the secure microcontroller. According to an advantageous embodiment, the secure microcontroller further comprises a random access memory, in which secret information is intended to be stored. According to an advantageous embodiment, secret information is intended to be stored permanently in the RAM, the microcontroller being intended to be powered permanently, the electronic module comprising means for erasing or altering the content of the RAM. on command. According to an advantageous embodiment, the means for erasing or altering the content of the random access memory comprise a wired logic function of the secure microcontroller. According to an advantageous embodiment, the random access memory is formed by a register. According to an advantageous embodiment, the secure microcontroller is configured so that any intrusion detection activates the command to erase or alter the content of the RAM. The invention has the advantage of making it possible to simply combine secure functions (electronic payment for example) with non-secure functions within the same device. It also allows the use of the same electronic payment module in different electronic payment devices, such as an electronic payment terminal and a confidential code entry box. It makes it possible to add electronic payment functions simply and in a modular way to a personal electronic assistant, while guaranteeing a level of security at least equal to that of conventional electronic payment terminals. Other characteristics and advantages of the invention will appear on reading the following detailed description presented by way of nonlimiting illustration and made with reference to the appended figures, which represent: FIG. 1, an example of an electronic module according to invention, in the form of a block diagram, FIG. 2, an example of an electronic payment terminal integrating a module according to the invention, FIG. 3, an example of a confidential code entry unit integrating a module according to the invention , Figure 4, an example of the programs stored in a permanent memory of a microcontroller of a module according to the invention, - Figure 5, an example of secure microcontroller according to an advantageous embodiment of the invention in which secret information, intended to be erased in the event of an intrusion, is permanently stored in a back-up RAM, FIG. 6, an example of di an analogy between an external processing unit and a secure microcontroller during authentication of the wearer.

We now refer to FIG. 1. An electronic module 1 according to the invention comprises hardware and software components. The hardware components can be mounted on an electronic card. The hardware components include for example a secure microcontroller 2 to which other peripheral components are connected. The peripheral components include, for example, a smart card interface 3 and a communication interface 4. The electronic module also comprises an anti-intrusion device 53 (see FIG. 5), delimiting a determined area around the secure components of the electronic module, and in particular around the secure microcontroller 2 and its secure links. The function of the anti-intrusion device is to detect any attempt at physical intrusion into this zone, hereinafter called "secure zone". It can take the form of a flexible circuit, having one or more conductive tracks which meander. This flexible circuit envelops the components to be protected (secure area) of the electronic module. The rupture or the electrical modification (setting to a fixed potential, short-circuit ...) of a track makes it possible to detect an intrusion. The secure microcontroller is a box that includes permanent memory, random access memory, and a microprocessor. Permanent memory allows data to be stored without power supply. Permanent memory is used to store software components, ie applications or parts of applications. An application is software that allows you to perform a particular task. An application can comprise several parts operating in interaction by exchanging data, these parts being executed by different microprocessors. Anyway, the permanent memory contains at least one secure software component intended to be executed by the microprocessor. The secure software component forms part or all of an electronic transaction application, such as an electronic payment application. The permanent memory can be a non-modifiable memory (known under the name of ROM, acronym for "Read Only Memory"), a reprogrammable memory, or an association of these memories. A reprogrammable memory is a memory that can be erased and reprogrammed, such as a FLASH or EEPROM memory (acronym of the Anglo-Saxon expression "Electrically Erasable Programmable Read Only Memory"). The random access memory makes it possible to store data during the execution of the applications, in particular of the secure software component. RAM is also known by the acronym RAM, from the Anglo-Saxon expression "Raπdom Access Memory". The smart card interface 3 comprises for example a connector intended to establish electrical connections with the contacts of a smart card. Alternatively, the smart card interface 3 includes an antenna formed by a magnetic loop, the antenna being intended to exchange radio frequency information with a smart card without contact. Anyway, the smart card interface is connected to an input / output port of the secure microcontroller. The communication interface 4 makes it possible to establish communication between the secure microcontroller 2 and the outside, that is to say with processing units external to the electronic module 1. The external processing unit can for example be a microprocessor an electronic assistant or a computer external to the device integrating the module 1. The external processing unit can also be a microprocessor external to the module, but internal to the device integrating the module 1. Thus, the external processing unit can be a microprocessor of an electronic payment terminal integrating module 1, this microprocessor being external to module 1. Advantageously, the communication interface is a standardized interface, synchronous or asynchronous, such as SPI (acronym of the English expression -saxon "Serial Peripheral Interface"), USB or UART. Advantageously, the electronic module comprises several different communication interfaces, each one being connected to the secure microcontroller. This allows greater interoperability of the electronic module. For example, the electronic module includes an SPI interface, a USB interface and two UART interfaces. Advantageously, the electronic module. Includes other peripheral components. According to an advantageous embodiment, the electronic module thus comprises one or more interfaces for secure memory cards 10, connected to the secure microcontroller 2, for storing secret information in secure memory cards. This makes it possible to have additional memories compared to the internal memory (permanent or living) of the secure microcontroller, these additional memories being themselves secure. The interfaces for secure memory cards can be four in number for example. Secure memory cards can be SAM cards (acronym for the English expression "Secure Access Module"). The secret information stored there can be secret keys of a bank acquirer, such as VISA, MASTERCARD or EUROPAY. According to an advantageous embodiment, the electronic module further comprises means for authenticating a card holder to chip, connected to the secure microcontroller. The execution of the secure software component implements a method for authenticating a smart card holder, the authentication method using said means for authenticating a holder. According to a first advantageous embodiment, the authentication means comprise input means 9, connected to the secure microcontroller, the input means being configured to receive secret information entered by the wearer. The secret information can for example be a confidential code, the authentication method being based on the knowledge of this confidential code by the holder. The input means can include a keyboard for example. In a practical embodiment, the authentication means of the electronic module further comprise display means 8, connected to the secure microcontroller. The display means are configured to allow the display of information for the wearer during the implementation of the authentication process. The information displayed may include, for example, an invitation to enter a confidential code. They may also include stars or other symbols, a star being displayed each time a character or number of the confidential code is entered by the holder. The display means can be formed by a screen, such as a liquid crystal screen. Alternatively, the display means can be formed by an array of individually controllable light elements, such as an array of light emitting diodes (LEDs). In another practical embodiment, the display means can be replaced by an interface to an external screen or any other display means. The external screen can be connected via a layer of wires to this interface. The connection between the interface and the external screen must then be secure (anti-intrusion detection), so as to ensure that the information displayed on the screen is indeed that transmitted by the secure microcontroller to the interface. According to a second advantageous embodiment (not shown), the authentication means are biometric means making it possible to authenticate a wearer by comparison of characteristics physiological of the wearer with data stored in the smart card. According to an advantageous embodiment independent of the previous ones, the electronic module further comprises a magnetic stripe card interface 7, connected to the secure microcontroller, to allow the reading of a magnetic stripe card by the secure microcontroller. The magnetic stripe interface comprises discrete components, such as a magnetic read head 7a and an integrated circuit 7b, the read head being connected to the integrated circuit, the integrated circuit being connected to the secure microcontroller. The integrated circuit can be a decoder, such as an F2F decoder, that is to say a circuit having the function of shaping the signals coming from the read head before their transmission to the secure microcontroller. According to an advantageous embodiment, the electronic module further comprises one or more memories 5, 6. The memories 5, 6 can be memories of the FLASH or RAM type. The memories are connected to the secure microcontroller. They increase the memory capacity of the secure microcontroller. They can be used by software components executed by the secure microcontroller, these software components not using secret information or using encrypted secret information. Reference is now made to FIG. 2. An electronic module according to the invention can be used to perform the electronic payment functions of an electronic payment terminal 20. It is thus possible to certify the electronic module to banking security standards independently of the other hardware components. and or software of the electronic payment terminal. These other hardware components can for example comprise a printer, this printer being intended for printing tickets. The electronic payment terminal 20 can comprise an electronic card 21 and a link 22 connected to the communication interface 4 of the electronic module 1. The electronic card 21 comprises a processing unit independent of the secure microcontroller, the processing unit allowing '' run insecure software components. The processing unit can be a microprocessor for example. Such insecure software components can be part of an electronic payment application, the secure software components of this application being executed by the secure microcontroller, the non-secure software components using the secure software components (see the example in FIG. 6). Reference is now made to FIG. 3. An electronic module according to the invention can be used to carry out the electronic payment functions of a box for entering confidential code 30. The box can comprise the electronic module 1 alone. The link 31 between the confidential code box 30 and a point of sale terminal (for printing tickets and recording the transactions) is then connected to the communication interface 4 of the electronic module. Thanks to the invention, it is thus possible to use the same electronic module in an electronic payment terminal and in a confidential code entry box. It is thus possible to carry out a certification of the electronic module, this certification benefiting both the electronic payment terminal and the confidential code entry box. It is also possible thanks to the invention to develop a range of electronic payment products, comprising for example personal electronic assistants integrating electronic payment functions, this range of products having a common electronic payment core, formed by the electronic module according to the invention. The communication interface, 4 (see FIG. 1) is intended to be connected to an external processing unit (for example a microprocessor), which is not necessarily secure. This processing unit can be an integral part of the electronic payment device in which the electronic module is placed, as in the example shown in FIG. 2. This processing unit can, on the contrary, be external to the electronic payment device itself. same, as in the example shown in Figure 3. We now refer to Figure 4. The microcontroller comprises one or more permanent memories 40 in which are stored software components. FIG. 4 represents a practical embodiment in which the microcontroller comprises two permanent memories: a reprogrammable memory of the EEPROM type and a non-modifiable memory (ROM). The different software components can be divided into layers, each layer comprising software components offering services to software components of an upper layer. A first layer 41, the lowest, can be stored in the ROM memory. This first layer includes a software primer, called "boot" in Anglo-Saxon literature. It may also include complementary services, such as cryptography services. A second layer 42, higher than the first, comprises interface drivers, called "drivers" in the Anglo-Saxon literature. For example, it can include an interface driver for the screen 8, for the keyboard 9, and for the memories 5, 6. This second layer, as well as the other upper layers, can be stored in the EEPROM memory, which allows, if necessary, to modify the content during software upgrades. A third layer 43, superior to the second, comprises a real-time operating system, also called the kernel. The operating system provides the hardware resources (interfaces, memories ...) to the applications of the last layer, and manages the multitasking operation. A fourth layer 44, higher than the third, comprises an application manager. The application manager directs messages from the .interfaces to the appropriate applications in the last layer. The fifth and last layer 45, higher than the fourth, comprises applications or parts of applications intended to perform a particular task. It can include part of an electronic payment application. Reference may be made to FIG. 6 for an example of the operation of such an application. Reference is now made to FIG. 5. According to an advantageous embodiment, the secure microcontroller further comprises a random access memory 52, in which secret information is intended to be stored. The RAM can be formed by a register of the secure microcontroller. The secret information can be cryptographic keys for example. This information is deleted in the event of a power failure. In addition, the memory being a random access memory, the erasure or the degradation of its information can be faster. The microcontroller can be powered by a main power supply 55, such as batteries or a transformer from alternating current to low voltage direct current. According to an advantageous embodiment, the electrical supply of the random access memory is saved. In other words, the random access memory is supplied by a reserve of electrical energy 11 making it possible to supply the random access memory when the main supply 55 is cut. The electrical energy reserve 11 can be a lithium battery, a battery or any other appropriate energy reserve. Secret information can thus be permanently stored in the backed up RAM. This secret information will be kept in the event of the main power supply 55 being cut, for example when the batteries are changed. A tilting device 56, which is an integral part of the secure microcontroller, can make it possible to switch between the main power supply 55 and the electrical energy reserve 11, in particular to supply the backup RAM memory of the microcontroller. According to an advantageous embodiment, the energy reserve 11 is an integral part of the electronic module according to the invention. In this way, electronic modules can be stored before being delivered and integrated into electronic payment devices, secret keys already being stored in the backed up RAM of the secure microcontroller. When an electronic module is integrated into an electronic payment terminal, the energy reserve of the electronic module likewise makes it possible to store this terminal without batteries, secret keys being stored in the secure microcontroller. In addition, the electronic module includes means for erasing or altering the content of the RAM on command. These means may include a wired logic function 51 of the secure microcontroller. In order to meet security standards requiring the destruction of all secret information in the event of an intrusion, the secure microcontroller is configured so that any intrusion detection activates the command to erase or alter the content of the RAM. If several anti-intrusion devices 53 are used, the signals from these devices can be combined at the input of a logic function 54 of the secure microcontroller, this logic function delivering a signal of single output after logical processing of the input signals, the output signal forming the command to erase or alter the contents of the RAM. Reference is now made to FIG. 6 in which is shown an example of dialogue between two parts of a payment application. The first part is an insecure software component 67, that is to say that does not use any secret data. The non-secure software component is executed by the external processing unit. The non-secure software component allows for example the management of a printer, the management of a modem, the management of radio communication means, etc. The second part is a secure software component 68, executed by the secure microcontroller. The secure software component implements the payment functions themselves. The authentication of the holder of a smart card will now be described. The non-secure component 67 sends a request 61 to the secure component 68, this request being an order to enter a transaction amount. The secure component 68 displays an invitation message on the screen, such as "amount?", And waits for a keyboard entry. After entering an amount, the secure component 68 sends a response to the non-secure component 67, the response containing the amount entered using the keyboard. The non-secure component 67 then sends a request 63 to the secure component 68, this request 63 comprising an order to enter the carrier code, and the amount to be displayed, this amount being the amount transmitted with the response 62. The secure component 68 displays the amount and an invitation message, such as "code:", and waits for a keyboard entry. After entering the code, the secure component sends a response to the non-secure component 67. This response does not include the code entered, but an indication whether this code has been entered or not. Thus, the non-secure component 67 does not process any secret information. The non-secure component, if the code has been entered, then sends a request 65 to the secure component, this request 65 comprising an order of presentation of the entered code to the smart card. The secure component presents the code entered on the card and waits for the card to respond. After receiving the response from the card, the secure component sends a response 66 to to the non-secure component 67, this response indicating whether the code entered is correct or not. A payment application based on the use of a track card can operate on the same principle, that is to say from two software components, one secure and the other not, the secure software component being executed. by the secure microcontroller and exchanging non-secure data with the non-secure software component. The secure software component may in particular carry out card reading operations, inputting the transaction amount, and encrypting a data block of an electronic transaction, said data block containing the information read from the card, the amount of the transaction, the time and date, and of the merchant's identification data (merchant number issued by the bank where his bank account is domiciled). According to an advantageous embodiment, the information leaving the secure microcontroller is only transmitted on the communication interface 4 if the request requesting this information has been previously signed and authenticated by the secure microcontroller. Any message not authenticated, badly or unsigned, does not send out any information entered in clear, neither on the screen, nor on a communication channel. Indeed, the information transmitted on the interface to the microcontroller can contain a text intended for. be displayed. This text can for example be an invitation to enter a confidential code, such as "Code?". If this message is not signed, no information will be sent back. This avoids any fraudulent use of the electronic module. According to another embodiment, the information transmitted on the interface to the microcontroller can contain a message code, this message code corresponding to a message to be displayed. For example, a table of predetermined messages can be stored in a memory of the secure microcontroller. If the message code is of the type an invitation to enter confidential information, then no information is transmitted in return. On the other hand, if the message code is of the type an invitation to enter the amount of the transaction, then the information entered following the display of this message can be transmitted in return. In this particular embodiment, it is not necessary to sign this type of information. Indeed, depending on the code of the message to be displayed, it is possible to determine the nature (confidential or non-confidential) of the information entered. Thus, if an unauthorized application is executed by the external processing unit, no secret information (confidential code, biometric information, etc.) can be recovered. The module according to the invention can be used for applications other than electronic payment. It generally applies to electronic transactions requiring a certain level of security. Mention may in particular be made of access control with badges, encryption of documents, certification of electronic data, electronic signature, etc. According to an advantageous embodiment, the communication link connected to the communication interface 4 can be secure in software, at the transport layer of the IP model (acronym for the English expression "Internet Protocol"). Thus, a merchant using a terminal incorporating such a module can thus exchange data with a bank via a secure Internet link. To this end, the electronic module includes secret keys and programs, stored in a memory located in the secure area. The programs allow you to implement encryption algorithms, such as RSA, SHA, DIFFIE-HELLMAN, MD5. They are used to secure a communication link of the Ethernet type in terms of confidentiality of the information exchanged on this link. The Ethernet type link connects the communication interface 4 (USB, SPI, UART ...) of the secure module to an IP gateway. The IP gateway can be implemented by means of a box, such as the MISTRAL box from the company THALES E-SECURITY or a box from the company CISCO. This gives a so-called "dry IP" link, an abbreviation of the Anglo-Saxon expression "Internet Protocol secured". On either side of the secure communication link, programs can communicate by implementing a protocol of the SSL type, acronym of the Anglo-Saxon expression "Secure Socket Layer". In other words, an electronic transaction software component of the secure module can communicate with a software component of a box. remote to which the module is connected, this communication implementing an application-to-application security protocol of the SSL type.

Claims

1. Electronic module (1) able to be used in an electronic transaction device, characterized in that the electronic module comprises at least:

- an anti-intrusion device, delimiting a secure area, configured to detect physical intrusions into the secure area,

a program memory (6), in the secure area, in which at least one secure software component of an electronic transaction application is stored,

- a microprocessor (2), in the secure area, connected to the program memory, intended to execute the secure software component,

- a communication interface (4) connected to the microprocessor, the communication interface being intended to connect the microprocessor to a processing unit external to the module so as to exchange data with the microprocessor.

2. Electronic module according to claim 1 wherein the electronic transaction application further comprises an unsecured software component intended to operate in interaction by exchanging non-confidential data with the secure software component, said non-confidential data being exchanged by the via the communication interface (4), the non-secure software component being intended to be executed by the external processing unit.

3. Electronic module according to claim 1 comprising means for securing software, at the transport layer of the IP model, the communication link intended to be connected to the communication interface (4), so as to guarantee the confidentiality of the data exchanged on this link with the microprocessor (2).

4. Module according to claim 1 further comprising a smart card interface (3), connected to the microprocessor so as to transmit requests from the microprocessor to a smart card and responses from the card to the microprocessor during the execution of the secure application.

5. Module according to claim 1 wherein the program memory and the microprocessor are an integral part of a microcontroller.

6. Module according to claim 1 further comprising at least one interface for secure memory card (10), connected to the secure microcontroller (2), for storing secret information in a secure memory card.

7. Module according to claim 1 further comprising means for authenticating a smart card holder (8, 9), connected to the secure microcontroller, the execution of the secure application implementing an authentication method of a smart card holder, the authentication method using said means of authenticating a holder.

8. Module according to claim 7, wherein the authentication means comprise input means (9), connected to the secure microcontroller, the input means being configured to receive secret information entered by the carrier.

9. Module according to claim 8 wherein the authentication means further comprise display means (8), connected to the secure microcontroller, the display means being configured to allow the display of information for the wearer during the implementation of the authentication process.

10. Module according to claim 9 wherein the display means are formed by a screen or a matrix of individually controllable light elements.

11. Module according to claim 7, in which the authentication means are biometric means making it possible to authenticate a wearer by comparing physiological characteristics of the wearer with data stored in the smart card.

12. Module according to claim 1, further comprising a magnetic stripe card interface (7), connected to the secure microcontroller, to allow the reading of a magnetic stripe card by the secure microcontroller.

13. Module according to claim 1, wherein the secure microcontroller further comprises a random access memory (52), in which secret information is intended to be stored.

14. Module according to claim 13, in which secret information is intended to be permanently stored in the random access memory, the microcontroller being intended to be permanently powered, the electronic module comprising means (54, 51) for erasing or alter the content of the RAM on command.

15. Module according to claim 14 wherein the means for erasing or altering the content of the random access memory comprise a wired logic function (51) of the secure microcontroller.

16. Module according to claim 14 wherein the random access memory is formed by a register.

17. Module according to claim 14 wherein the secure microcontroller is configured so that any intrusion detection activates the command to erase or alter the content of the RAM.