Providing a user device with a set of a access codes
A method for providing a user device with a set of access codes comprises, in the user device, storing an encryption key and an identification code, and sending a message containing the identification code to a server via a communications network. In the server, an encryption key is stored corresponding to the key stored in the user device, allocating the set of access codes on receipt of the identification code from the user device. A look up function is performed based on the identification code received in the message to retrieve the key from storage. The set of access codes is encrypted using the retrieved key to produce an encrypted set. A message containing the encrypted set is sent to the user device via the network. In the user device, the encrypted set received from the server is decrypted using the key in storage, and storing the decrypted set of access codes for use by a user of the user device.
The present invention generally relates to methods, apparatus, and computer program elements for providing a user device with sets of access codes such as one time authentication codes via data communications networks such as wireless communications networks.
One time authentication codes (OTACS) with paper based scratch lists of transaction authentication numbers (TANS) or one time credit card numbers are increasingly popular in the field of on line transactions. It would be desirable to permit secure storage and distribution of OTACs. It would be equally desirable to permit convenient access to OTACs wherever and whenever needed. Unfortunately, paper based scratch lists are both relatively insecure and inconvenient to access. Typically, a scratch list is sent from a service provider such as a bank to a customer via plain mail. A mailed scratch list can be intercepted en route to the customer and copied. In addition, many customers cannot be relied upon to store scratch lists in a secure location such as a safe. This is especially the case where the scratch list is used regularly. A regularly used scratch list may be left in the open, on a desk for example. This provides others with access to the scratch list. If a scratch list is carried by a customer, it may be lost or stolen. OTACs on scratch lists are not usually encrypted. Customer account numbers, which are generally combined with an OTAC to effect a transaction, are widely regarded as being publicly known. It is inconvenient for many customers to manually keep track of which OTACs have been used. When moving from one scratch list to another, customers need to temporarily store or carry two scratch lists. This enhances security risk. Furthermore, paper based scratch lists are complicated for the issuing service providers to print and mail in a timely manner.
WO98/37524 describes a transaction method using a mobile device. This method employs International Debit User Identification (IDUI) numbers to identify individual accounts. The IDUI is analogous to a customer bank account number. Specifically, the IDUI is pre-loaded onto credit/debit card. In operation, a point of sale (POS) terminal reads the IDUI from a credit/debit card and display an amount to be deducted from an identified account. The customer completes the transaction by pressing an OK button of the POS terminal. The POS terminal sends a transaction receipt to a server in the bank responsible for the account. WO98/37524 proposes pre-storing the IDUI on a Subscriber Identification Module (SIM) smart card as used in GSM mobile phone networks instead of on a magnetic strip or memory card. The IDUI is then read from the smart card by the terminal in a contact-less manner. Transaction receipts are sent to the server for verification by SMS messages. This scheme discusses only the uses of IDUIs for transactions with POS terminals via a contact-less interface and exchanging SMS messages for transaction verification. The scheme is not suitable for OTAC delivery. This is because IDUIs are fixed for each account. OTACs, however, are not. Similar electronic payment systems are described in EP1 176 844, WO99/16029, WO00/495585, WO01/09851, WO02/21464, and WO01/93528.
In accordance with the present invention, there is now provided a method for providing a user device with a set of access codes, the method comprising: in the user device, storing an encryption key and an identification code, and sending a message containing the identification code to a server via a communications network; in the server, storing an encryption key corresponding to the key stored in the user device, allocating the set of access codes on receipt of the identification code from the user device, performing a look up function based on the identification code received in the message to retrieve the key from storage, encrypting the set of access codes using the retrieved key to produce an encrypted set, and sending a message containing the encrypted set to the user device via the network; and, in the user device, decrypting the encrypted set received from the server using the key in storage, and storing the decrypted set of access codes for use by a user of the user device.
This advantageously provides a scheme for providing access codes such as OTACs to customers in a convenient yet secure manner.
Preferably, the method further comprises: in the server, generating a new key, encrypting the new key with the previous key, and sending a message containing the encrypted new key to the user device via the network; and, in the user device, decrypting the new key received from the server using the previous key, and storing the decrypted new key in place of the previous key.
This advantageously provides additional security by facilitating secure refreshment of keys employed.
The method may also extend to, in the server, encrypting a new set of access codes with the new key to produce a new key encrypted set, and sending a message containing the new key encrypted set to the user device via the network; and, in the user device, decrypting the new key encrypted set using the new key, and storing the decrypted new set for use by a user of the user device.
This advantageously provides for secure refreshment of the access codes in a convenient manner.
Preferably, the method further comprises: in the server, sending a message containing a new set of access codes to the user device via the network; and, in the user device, storing the new set for use by a user of the user device. The method may further comprise: in the user device, tracking the access codes used by the user, generating a request in response to the number of unused access codes reaching a predetermined threshold, and sending a message containing the request to the server; and, in the server, sending the message containing the new set of access codes on receipt of the request. Alternatively, the method may comprise: in the server, tracking the access codes used by the user, and sending the message containing the new set of access codes to the user device in response to the number of unused access codes reaching a predetermined threshold. In another alternative, the method may comprise: in the user device, generating a request in response to a manual input from the user, and sending a message containing the request to the server; and, in the server, sending the message containing the new set of access codes on receipt of the request.
In a preferred embodiment of the present invention, the method further comprises: in the user device, generating a public/private key pair, and sending a message containing the public key of the pair to the server via the network; in the server, generating a session key, encrypting the set of access codes with the session key to produce a session key encrypted set, encrypting the session key with the public key to produce an encrypted session key, sending a message containing the session key encrypted set and the encrypted session key to the user device via the network; and, in the user device, decrypting the encrypted session key with the private key of the pair to recover the session key, decrypting the session key encrypted set with the recovered session key to recover the set, and storing the decrypted set for use by a user of the user device.
This advantageously provides further security via multiple key encryption.
Viewing the present invention from another aspect, there is now provided a method for providing a user device with a set of access codes, the method comprising, in the user device: storing an encryption key and an identification code; sending a message containing the identification code to a server via a communications network; receiving from the server a message containing the set of access codes encrypted with the key; decrypting the received set of access codes using the key in storage; and, storing the decrypted set of access codes for use by a user of the user device. The present invention also extends to a computer program element comprising computer program code mean when loaded in a processor of a user device, configures the processor to perform a method as described in this paragraph.
Viewing the present invention from yet another aspect, there is now provided, a method for providing a user device with a set of access codes, the method comprising, in a server for communicating with the user device via a network: storing an encryption key corresponding to an encryption key stored in the user device; allocating the set of access codes to the user device on receipt of a message containing an identification code from the user device via the network; performing a look up function based on the identification code received in the message to retrieve the key from storage; encrypting the set of access codes using the retrieved key to produce an encrypted set; and, sending a message containing the encrypted set to the user device via the network. The present invention also extends to a computer program element comprising computer program code mean when loaded in a processor of a server computer system, configures the processor to perform a method as described in this paragraph.
In a particularly preferred embodiment of the present invention, the access codes are one time authentication codes. Similarly, in a preferred embodiment of the present invention, the network comprises a wireless communication network. The user device may comprise a mobile phone. Similarly, the user device may comprise a smart card. I an especially preferred embodiment of the present invention, the messages are SMS messages.
Viewing the present invention from still another aspect, there is now provided apparatus for providing a user with a set of access codes, the apparatus comprising: a user device; and, server for communicating with the user device via a communications network; the user device comprising means for storing an encryption key and an identification code, and means for sending a message containing the identification code to the server via the network; the server comprising means for storing an encryption key corresponding to the key stored in the user device, means for allocating the set of access codes on receipt of the identification code from the user device, means for performing a look up function based on the identification code received in the message to retrieve the key from storage, means for encrypting the set of access codes using the retrieved key to produce an encrypted set, and means for sending a message containing the encrypted set to the user device via the network; and, the user device further comprising means for decrypting the encrypted set received from the server using the key stored in the user device, and means for storing the decrypted set of access codes for use by the user.
The present invention further extends to a user device for receiving a set of access codes from a server via a communications network, the device comprising: means for storing an encryption key and an identification code; means for sending a message containing the identification code to a server via a communications network; means for receiving from the server a message containing the set of access codes encrypted with the key; means for decrypting the received set of access codes using the key in storage; and, means for storing the decrypted set of access codes for use by a user of the user device.
Additionally, the present invention extends to a server for providing a user device with a set of access codes via a communications network, the server comprising: means for storing an encryption key corresponding to an encryption key stored in the user device; means for allocating the set of access codes to the user device on receipt of a message containing an identification code from the user device via the network; means for performing a look up function based on the identification code received in the message to retrieve the key from storage; means for encrypting the set of access codes using the retrieved key to produce an encrypted set; and, means for sending a message containing the encrypted set to the user device via the network.
In a preferred embodiment of the present invention, there is provided a secure transaction scheme which is both more secure and more convenient for both customers and, for example, banking service providers compared with conventional schemes. A particularly preferred embodiment of the present invention comprises: a smart card on which one or more scratch lists are stored in a tamper resistant manner; a mobile device for conveniently accessing the scratch lists stored on the smart card; and, encrypted messaging over a wireless communications channel between the mobile device and a server computer for updating the scratch lists stored on the smart card. Advantageously, no assumptions need be made regarding the security or encryption capabilities of the wireless communications channel. The mobile device may be a mobile phone, personal digital assistant (PDA) or the like. The smart card may be a SIM module for insertion into a mobile phone or the like. The wireless communications channel may be a Short Message Service (SMS) in a GSM channel or the like.
In a particularly preferred embodiment of the present invention to be described shortly, the mobile device is implemented by a mobile phone; the smart card is implemented by a SIM module, and the wireless communications channel is implemented by an SMS channel in a GSM network. In this embodiment, the customer is equipped with a mobile phone having a SIM module. The SIM module comprises a central processing unit and a memory. Java (trademark of Sun Microsystems) compatible operating platform software and Java tool kit applet software are stored in the memory. The operating platform software configures the CPU for executing the tool kit. The tool kit facilitates handling of OTACs. The tool kit may be loaded into the memory during personalizing of the SIM for the customer. Alternatively, if permitted by the GSM network service provider, the tool kit may be loaded into the memory and refreshed dynamically via the GSM network. Access to the tool kit in the memory is protected by a Personal Identification Number (PIN) set by the customer via the mobile phone.
In an especially preferred embodiment of the present invention, a bank sends the customer an initializing paper mail via the conventional postal system. The initializing paper mail contains: a customer specific symmetrical key K, such as a 16 byte DES key; a customer identification (ID) code N; and a phone number for an SMS compatible server at the bank. The ID code N is used by the bank to identify the customer. The ID code need not be the customer's account number and may instead be implemented by unique random information.
On initial activation by the customer, the tool kit asks the customer to enter the key K, the information N, and the phone number of the server via the keypad of the mobile phone. The tool kit then sends an initialization SMS message containing the identification code N to the server. The initialization message indicates that the tool kit is enabled. The server responds to receipt of the initialization message by sending an SMS reply message to the customer containing a list of OTACs encrypted with the key K. The OTAC list may be spread across a series of SMS messages depending on the amount of data to transferred. The tool kit decrypts the OTAC list received using the key K. Initialization is then complete. When the customer needs an OTAC, to perform an on-line banking transaction over the Internet for example, the customer again enters the PIN into the mobile phone to unlock the tool kit and requests from the tool kit the next OTAC or a specific OTAC, depending on the bank's OTAC allocation system. The tool kit keeps track of the OTACs issued. When all the OTACs stored by the tool kit have been issued, a new OTAC list is obtained from the server. The new list is again delivered via the SMS channel as herein before described. The server also keeps track of how many and which OTACs have been used by each customer at any time, and automatically initiates updates when required. Note this scheme involves only an end to end encryption between the server and the tool kit in the customer's SIM module. No assumptions need be made regarding the security of the intervening wireless channel.
In another preferred embodiment of the present invention, the key K can be updated on demand by sending a new key K′ encrypted with the key K to the tool kit from the server via the wireless channel. Thereafter, the tool kit accepts only messages encrypted with the new key K′. Distribution of the new key K′ may be performed with distribution of new OTAC lists. Alternatively, distribution of the new key K′ may be performed independently of new OTAC list distribution.
In yet another preferred embodiment of the present invention, the server may send another key S encrypted with the key K to the tool kit via the wireless channel. The other key S may be used for signature verification for example. Further messages from the server are then signed with the signature key S prior to being encrypted with the key K. The tool kit can then verify the signature accordingly.
In a further embodiment of the present invention, asymmetric cryptography is employed in place of the symmetric cryptography herein before described. In this case, the customer need not manually enter the initial symmetric key K. Instead, the tool kit generates a public/private key pair, such as a 1024 bit RSA key pair, on the SIM module. The tool kit then enables itself by sending the public key E together with the ID code N to the server via the communications channel. For each message to the tool kit, the server now generates a symmetric session key. In each case, the server encrypts the message with the secure session key, encrypts the session key with the public key E, and sends the encrypted message, together with the encrypted session key to the tool kit via the wireless channel. The tool kit decrypts the session key with it private key D. The tool kit then decrypts the or each message using the decrypted session key to recover the OTAC list.
The server may also employ a public/private key pair for signature generation and verification, sending its public key to the tool kit for future verification actions. Note that the server may issue the same public key for signature verification to all tool kits, possibly signed by a trusted third party certificate authority having a public key pre-stored on the smart card.
In a further embodiment of the present invention, at least one of the mobile device and the smart card comprises a contact-less interface such as an infrared or inductive interface. The interface permits access to the tool kit on the smart card via a data terminal. OTACs can be read through the interface on issuance of a request from the customer via the data terminal. Such a request may be issued for example via a keyboard of the data terminal. Alternatively, OTACs may be read through the interface without requiring such manual requests. Various challenge and response schemes may be employed between the smart card and the data terminal. For example, the data terminal itself may not gain access to the OTAC. Instead, the data terminal may send a challenge to the tool kit. In turn, the tool kit generates a response to the challenge based on the OTAC. For example, if the OTAC effectively comprises a cryptographic key, such as a 3 DES key, the tool kit may digitally sign and/or encrypt the challenge with the OTAC. The response thus calculated may be used for authentication or to enable a transaction.
It will be appreciated that advantages of the present invention are manifold. One advantage of the present invention in that it provides a secure technique for distributing OTACs to user devices. Examples of such user devices include mobile devices equipped with tamper resistant smart card technology, without preventing convenient access to the OTACs whenever and wherever needed. Such access can be manually initiated or automatically initiated via a wireless channel. The present invention is particularly attractive for banking applications because no changes are required to typical computer infrastructures conventionally employed in banks. Distribution of OTAC lists is made cheaper, simpler, and more secure. Furthermore, utilizing existing infrastructure means that no additional OTAC specific mobile devices and/or smart cards need be issued to customers already in possession of a mobile phone with a SIM card that allows downloading and execution of tool kit applets.
Preferred embodiment of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:
Referring first to
With reference now to
Referring to
With reference to
In operation, a wireless communication channel in the form of an SMS channel is established between the user device 100 and the server 200. The SMS channel facilitates secure transfer of the scratch list 80 from the OTAC service 260 in the server 200 to the smart card 10 via the user device 100. The tool kit 70 may be loaded into the memory 20 of the user device 100 during configuration of the smart card 10 for the user. Alternatively, if permitted by the network infrastructure 300, the tool kit 70 may be loaded into the memory 20 and refreshed dynamically via the network infrastructure 300. Access to the tool kit 70 in the memory 20 is protected by a PIN set by the user via the user device 100. The keypad 160 may be employed for this purpose. Alternatively, if the user device 100 has voice recognition, the PIN may be set and reset orally. Other devices may support still further means of data entry.
In a particularly preferred application of the present invention, the server 200 is located at a bank and the user of the user device 100 is a customer of the bank. Initially, the bank supplies the user with a paper mail. The paper mail may be supplied via, for example, the conventional postal system. The paper mail contains: a customer specific symmetrical key K, such as a 16 byte DES key; a customer identification (ID) code N; and a phone number for accessing the server 200 via the network infrastructure 300. The banks uses the ID code N to identify the user. The ID code need not be the user's customer account number and may instead be implemented by unique random information.
Referring now to
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Turning to
Referring now to
Numerous methods may be employed for refreshing the list 80 of OTACs stored in the memory 20. For example, in a preferred embodiment of the present invention, refreshment of the list 80 of OTACs is automatically triggered by the tool kit 70. Specifically, referring to
In a modification to the preferred embodiment of the present invention herein before described with reference to FIGS. 5 to 11, the key K stored in the memory 20 can be updated on demand. Specifically, referring to
Referring to
In another modification of preferred embodiment of the present invention herein before described with reference to FIGS. 5 to 11, the OTAC service 260 sends another key S encrypted with the key K to the tool kit 70 via the network infrastructure 300. The other key S may be used for signature verification for example. Further messages from the OTAC service 260 are then signed with the signature key S prior to encryption with the key K. The tool kit 70 can then verify the signature accordingly. Keys K and S are not necessarily different.
In the preferred embodiments of the present invention herein before described, symmetric cryptography is employed. However, in another embodiment of the present invention, asymmetric cryptography is employed. In this embodiment, the user need not manually enter the initial symmetric key K. Referring to
Referring now to
In a preferred embodiment of the present invention, the OTAC service 260 also employs a public/private key pair for signature generation and verification. The OTAC service 260 sends its public key to the tool kit 70 for future verification actions. Note that the OTAC service 260 may issue the same public key for signature verification to all tool kits 70 it services, possibly signed by a trusted third party certificate authority having a public key pre-stored on the smart card 10.
Referring to
In operation, OTACs can be read by the data terminal 810 from the smart card 10 resident in the user device 100 via the interfaces 800 and 880 in response to a request issued by the customer via the keypad 830 of the date terminal 810. Alternatively, OTACs may be read by the data terminal 810 through the interfaces 800 and 880 without requiring such manual requests. Various challenge and response schemes may be employed between the smart card 10 and the data terminal 810. For example, in a preferred embodiment of the present invention, the data terminal 810 does not gain access to the OTACs. Instead, the data terminal 810 sends a challenge to the tool kit 70 in the smart card 10. In turn, the tool kit 70 generates a response to the challenge based on the OTAC. For example, if the OTAC effectively comprises a cryptographic key such as a 3 DES key, the tool kit 70 may digitally sign and encrypt the challenge with the OTAC. The response thus calculated may be used for authentication or to enable a transaction. In other embodiments of the present invention, the contact less interface 800 may be integral to the smart card 800 rather than the user device 100.
In the preferred embodiments of the present invention herein before described, the user device 100 is in the form of a mobile phone. However, in other embodiments of the present invention, the user device 100 may be of a different form, such as a PDA, portable computer, desktop computer, or the like. Similarly, in the preferred embodiments of the present invention herein before described, a wireless network is employed for effecting communications between the user device 100 and the server 200. However, in other embodiments of the present invention a wired network or a combination of wireless and wired networks may be employed for effecting communications between the user device 100 and the server 200. Additionally, in the preferred embodiments of the present invention herein before described, wireless communications between the user device 100 and the server 200 are effected via an SMS channel. However, in other embodiments of the present invention, a different form of messaging service may be employed. Furthermore, in the preferred embodiments of the present invention herein before described, the smart card 10 is in the form of a SIM module. However, in other embodiments of the present invention, the smart card 10 may be in different form, such as a credit or charge card form factor. Other analogous forms of dedicated processor systems may be employed in place of the smart card 10. In the embodiments of the present invention, a Java compliant operating system 60 is employed in the smart card 10 for executing the tool kit 70 in the form of a Java applet. However, in other embodiments of the present invention, a different form of smart card operating system and a correspondingly different form of tool kit application software may be employed. Still furthermore, in the preferred embodiments of the present invention, the access codes are in the form of one time authentication codes. However, it will be appreciated that the present invention is equally applicable to delivery of other types of access codes, such as entry codes for gaining access to restricted areas, for example. Many other applications of the present invention will be apparent.
In summary, described herein by way of example of the present invention is a method for providing a user device with a set of access codes comprises, in the user device, storing an encryption key and an identification code, and sending a message containing the identification code to a server via a communications network. In the server, an encryption key is stored corresponding to the key stored in the user device, allocating the set of access codes on receipt of the identification code from the user device. A look up function is performed based on the identification code received in the message to retrieve the key from storage. The set of access codes is encrypted using the retrieved key to produce an encrypted set. A message containing the encrypted set is sent to the user device via the network. In the user device, the encrypted set received from the server is decrypted using the key in storage, and storing the decrypted set of access codes for use by a user of the user device.
Claims
1. A method for providing a user device with a set of access codes, the method comprising:
- in the user device, storing an encryption key and an identification code, and sending a message containing the identification code to a server via a communications network;
- in the server, storing an encryption key corresponding to the key stored in the user device, allocating the set of access codes on receipt of the identification code from the user device, performing a look up function based on the identification code received in the message to retrieve the key from storage, encrypting the set of access codes using the retrieved key to produce an encrypted set, and sending a message containing the encrypted set to the user device via the network; and,
- in the user device, decrypting the encrypted set received from the server using the key in storage, and storing the decrypted set of access codes for use by a user of the user device; and,
- upon the number of unused access codes reaching a predetermined threshold, in the server, sending a message containing a new set of access codes to the user device via the network; and,
- in the user device, storing the new set for use by a user of the user device.
2. A method as claimed in claim 1, further comprising:
- in the user device, tracking the access codes used by the user, generating a request in response to the number of unused access codes reaching a predetermined threshold, and sending a message containing the request to the server; and,
- in the server, sending the message containing the new set of access codes on receipt of the request.
3. A method as claimed in claim 1, further comprising: in the server, tracking the access codes used by the user, and sending the message containing the new set of access codes to the user device in response to the number of unused access codes reaching a predetermined threshold.
4. A method as claimed in claim 1, further comprising:
- in the server, generating a new key, encrypting the new key with the previous key, and sending a message containing the encrypted new key to the user device via the network; and, in the user device, decrypting the new key received from the server using the previous key, and storing the decrypted new key in place of the previous key.
5. A method as claimed in claim 4, further comprising:
- in the server, encrypting a new set of access codes with the new key to produce a new key encrypted set, and sending a message containing the new key encrypted set to the user device via the network; and,
- in the user device, decrypting the new key encrypted set using the new key, and storing the decrypted new set for use by a user of the user device.
6. A method as claimed in claim 1, further comprising:
- in the user device, generating a public/private key pair, and sending a message containing the public key of the pair to the server via the network;
- in the server, generating a session key, encrypting the set of access codes with the session key to produce a session key encrypted set, encrypting the session key with the public key to produce an encrypted session key, sending a message containing the session key encrypted set and the encrypted session key to the user device via the network; and,
- in the user device, decrypting the encrypted session key with the private key of the pair to recover the session key, decrypting the session key encrypted set with the recovered session key to recover the set, and storing the decrypted set for use by a user of the user device.
7. A method for providing a user device with a set of access codes, the method comprising, in the user device:
- storing an encryption key and an identification code;
- sending a message containing the identification code to a server via a communications network;
- receiving from the server a message containing the set of access codes encrypted with the key;
- decrypting the received set of access codes using the key in storage; and,
- storing the decrypted set of access codes for use by a user of the user device.
- upon the number of unused access codes reaching a predetermined threshold, receiving from the server a message containing a new set of access codes; and,
- in the user device, storing the new set for use by a user of the user device.
8. A method as claimed in claim 7, further comprising: in the user device, tracking the access codes used by the user, generating a request in response to the number of unused access codes reaching a predetermined threshold, and sending a message containing the request to the server.
9. A method as claimed in claim 7, further comprising, in the user device:
- decrypting a new key received from the server using the previous key; and,
- storing the decrypted new key in place of the previous key.
10. A method as claimed in claim 9, further comprising, in the user device:
- receiving from the server a message containing a new key encrypted set of access codes via the network;
- decrypting the new key encrypted set using the new key; and,
- storing the decrypted new set for use by a user of the user device.
11. A method as claimed in claim 7, comprising, in the user device:
- generating a public/private key pair;
- sending a message containing the public key of the pair to the server via the network;
- receiving a message containing a session key encrypted set of access codes and a public key encrypted session key from the server via the network;
- decrypting the public key encrypted session key with the private key of the pair to recover a session key encrypted set and a corresponding session key;
- decrypting the session key encrypted set with the recovered session key to recover the set; and,
- storing the decrypted set for use by a user of the user device.
12. A computer program element comprising computer program code mean when loaded in a processor of a user device, configures the processor to perform a method as claimed in claim 7.
13. A method for providing a user device with a set of access codes, the method comprising, in a server for communicating with the user device via a network:
- storing an encryption key corresponding to an encryption key stored in the user device;
- allocating the set of access codes to the user device on receipt of a message containing an identification code from the user device via the network;
- performing a look up function based on the identification code received in the message to retrieve the key from storage;
- encrypting the set of access codes using the retrieved key to produce an encrypted set; and,
- sending a message containing the encrypted set to the user device via the network; and,
- upon the number of unused access codes reaching a predetermined threshold, sending a message containing a new set of access codes to the user device via the network.
14. A method as claimed in claim 13, further comprising, in the server:
- generating a new key, encrypting the new key with the previous key; and,
- sending a message containing the encrypted new key to the user device via the network.
15. A method as claimed in claim 14, further comprising, in the server:
- encrypting the new set of access codes with the new key to produce a new key encrypted set of access codes.
16. A method as claimed in claim 13, further comprising, in the server:
- receiving a message containing a public key of a public/private key pair from the user device;
- generating a session key;
- encrypting the set of access codes with the session key to produce a session key encrypted set;
- encrypting the session key with the public key to produce a public key encrypted session key; and,
- sending a message containing the session key encrypted set and the public key encrypted session key to the user device via the network.
17. A computer program element comprising computer program code means when loaded in a processor of a server computer system, configures the processor to perform a method as claimed in claim 13.
18. A method as claimed claim 1, further comprising a limitation taken from a group of limitations consisting of:
- wherein the access codes are one time authentication codes;
- wherein the network comprises a wireless communication network;
- wherein the user device comprises one of a mobile phone, a personal digital assistant, and a smart card; and
- wherein the messages are SMS messages.
19-21. (canceled)
22. An apparatus for providing a user with a set of access codes, the apparatus comprising: a user device; and, server for communicating with the user device via a communications network; the user device comprising
- means for storing an encryption key and an identification code, and
- means for sending a message containing the identification code to the server via the network; the server comprising
- means for storing an encryption key corresponding to the key stored in the user device,
- means for allocating the set of access codes on receipt of the identification code from the user device,
- means for performing a look up function based on the identification code received in the message to retrieve the key from storage,
- means for encrypting the set of access codes using the retrieved key to produce an encrypted set, and
- means for sending a message containing the encrypted set to the user device via the network and for sending upon the number of unused access codes reaching a predetermined threshold, a message containing a new set of access codes to the user device via the network; and, in the user device, storing the new set for use by a user of the user device.
- and, the user device further comprising:
- means for decrypting the encrypted set received from the server using the key stored in the user device, and
- means for storing the decrypted set of access codes for use by the user.
23. Apparatus as claimed in claim 22, wherein the server further comprises
- means for generating a new key,
- means for encrypting the new key with the previous key, and
- means for sending a message containing the encrypted new key to the user device via the network, and wherein the user device further comprises
- means for decrypting the new key received from the server using the previous key, and
- means for storing the decrypted new key in place of the previous key.
24. Apparatus as claimed in claim 23, wherein the server further comprises
- means for encrypting the new set of access codes with the new key to produce a new key encrypted set; and
- means for sending a message containing the new key encrypted set to the user device via the network, and wherein the user device further comprises
- means for decrypting the new key encrypted set using the new key, and
- means for storing the decrypted new set for use by a user of the user device.
25. Apparatus as claimed in claim 22, further comprising at least one element taken from a group of elements consisting of: in the user device:
- means for storing the new set for use by a user of the user device;
- means for tracking the access codes used by the user,
- means for generating a request in response to the number of unused access codes reaching a predetermined threshold, and
- means for sending a message containing the request to the server; and
- means for generating a request in response to a manual input from the user, and
- means for sending a message containing the request to the server; and
- in the server,
- means for sending the message containing the new set of access codes on receipt of the request; and
- means for sending the message containing the new set of access codes on receipt of the request.
26. (canceled)
27. Apparatus as claimed in claim 25, further comprising: in the server,
- means for tracking the access codes used by the user, and
- means for sending the message containing the new set of access codes to the user device in response to the number of unused access codes reaching a predetermined threshold.
28. Apparatus as claimed in claim 25, further comprising: in the user device,
- means for generating a request in response to a manual input from the user, and
- means for sending a message containing the request to the server; and, in the server,
- means for sending the message containing the new set of access codes on receipt of the request.
29. Apparatus as claimed in claim 22, wherein the user device further comprises
- means for generating a public/private key pair and
- means for sending a message containing the public key of the pair to the server via the network; wherein the server further comprises
- means for generating a session key,
- means for encrypting the set of access codes with the session key to produce a session key encrypted set,
- means for encrypting the session key with the public key to produce a public key encrypted session key, and
- means for sending a message containing the session key encrypted set and the public key encrypted session key to the user device via the network; and, wherein the user device further comprises
- means for decrypting the public key encrypted session key with the private key of the pair to recover the session key,
- means for decrypting the session key encrypted set with the recovered session key to recover the set, and
- means for storing the decrypted set for use by a user of the user device.
30. An apparatus as claimed in claim 22, further comprising a limitation taken from a group of limitations consisting of:
- wherein the access codes are one time authentication codes,
- the user device comprises one of a mobile phone, a personal digital assistant, and a smart card; and
- wherein the messages are SMS messages.
31-33. (canceled)
34. A user device for receiving a set of access codes from a server via a communications network, the device comprising:
- means for storing an encryption key and an identification code;
- means for sending a message containing the identification code to a server via a communications network;
- means for receiving from the server a message containing the set of access codes encrypted with the key;
- means for decrypting the received set of access codes using the key in storage; and,
- means for storing the decrypted set of access codes for use by a user of the user device; and
- means for receiving upon the number of unused access codes reaching a predetermined threshold from the server a message containing a new key encrypted set of access codes via the network.
35. A user device as claimed in claim 34, further comprising:
- means for decrypting a new key received from the server using the previous key; and,
- means for storing the decrypted new key in place of the previous key.
36. A user device as claimed in claim 35, further comprising:
- means for decrypting the new key encrypted set using the new key; and,
- means for storing the decrypted new set for use by a user of the user device.
37. A user device as claimed in claim 34, further comprising:
- means for generating a public/private key pair;
- means for sending a message containing the public key of the pair to the server via the network;
- means for receiving a message containing a session key encrypted set of access codes and a public key encrypted session key from the server via the network;
- means for decrypting the public key encrypted session key with the private key of the pair to recover the session key;
- means for decrypting the session key encrypted set with the recovered session key to recover the set; and,
- means for storing the decrypted set for use by a user of the user device.
38. A server for providing a user device with a set of access codes via a communications network, the server comprising:
- means for storing an encryption key corresponding to an encryption key stored in the user device;
- means for allocating the set of access codes to the user device on receipt of a message containing an identification code from the user device via the network;
- means for performing a look up function based on the identification code received in the message to retrieve the key from storage;
- means for encrypting the set of access codes using the retrieved key to produce an encrypted set; and,
- means for sending a message containing the encrypted set to the user device via the network,
- means for sending upon the number of unused access codes reaching a predetermined threshold a message containing the new set of access codes to the user device via the network.
39. A server as claimed in claim 38, further comprising at least one element taken from a group of elements consisting of:
- means for generating a new key, encrypting the new key with the previous key, and
- means for sending a message containing the encrypted new key to the user device via the network;
- means for encrypting the new set of access codes with the new key to produce a new key encrypted set;
- means for receiving a message containing a public key of a public/private key pair from the user device,
- means for generating a session key,
- means for encrypting the set of access codes with the session key to produce a session key encrypted set,
- means for encrypting the session key with the public key to produce a public key encrypted session key, and
- means for sending a message containing the session key encrypted set and the public key encrypted session key to the user device via the network.
40-41. (canceled)
Type: Application
Filed: Oct 24, 2003
Publication Date: Jul 27, 2006
Inventors: Michael Baentsch (Gross), Peter Buhler (Gross), Thomas Eirich (Waedenswil), Frank Hoering (Zurich), Thorsten Kramp (Kilchberg), Marcus Oestreicher (Zurich), Michael Osborne (Au), Thomas Weigold (Thalwil)
Application Number: 10/532,195
International Classification: G06F 12/14 (20060101);