The present invention relates to telecommunication systems and in particular to a method and system for calling line authenticated key distribution.
Servers on computer networks, such as the Internet, can provide secure services to users. Users are often required to provide an authenticated key to gain access to such secured services. Several methods can be used to distribute authenticated keys to authorized users. For example, an authenticated key can be printed on paper and mailed to an authorized user's home. In some situations, it may be desired to distribute authenticated keys electronically, such as with a server on the computer network. However, distributing authenticated keys this way can be problematic since it can be difficult to verify that the person requesting an authenticated key is an authorized user. For example, if a password is used to verify the identity of a person requesting an authenticated key, the server providing the key cannot differentiate between an authorized user and an imposter who stole the authorized user's password. Moreover, the problems of password distribution and key distribution are similar: passwords that provide high security (e.g., an arbitrary 128-character string) are too difficult to distribute by voice, and passwords that are easy to distribute by voice provide little security.
There is a need, therefore, for a method and system that can be used to distribute authenticated keys that overcomes the disadvantages described above.
The various embodiments of the present invention yield several advantages over the prior art. By way of introduction, a telephone network is used in combination with a computer network to distribute authentication keys to take advantage of the telephone network's ability to identify a calling party. In one preferred embodiment, an authentication key is provided to a calling party if the calling party is phoning from a calling line associated with an authorized user. This preferred embodiment provides a more secure authentication key distribution method as compared to the prior art since preventing an unauthorized user from gaining access to an authorized user's calling line is more feasible and reliable than attempting to prevent an unauthorized user from obtaining an authorized user's password. Other preferred embodiments are provided, and each of the preferred embodiments described below can be used alone or in combination with one another.
Turning now to the drawings,
The calling party 100 connects to the telephone network 130 via a calling line 180. The calling line 180 is identified by a calling line identifier. The calling line identifier can take any suitable form and, in one embodiment, is a directory number (e.g., the calling party's telephone number). In this preferred embodiment, the telephone network 130 is part of a public-switched telephone network and is implemented as an advanced intelligent network (“AIN”), such as the Signal System 7 (“SS7”) network. The telephone network 130 comprises a service switching point (“SSP”) 140, a service control point (“SCP”) 150, and a database 160. In this embodiment, the SSP 140 and SCP 150 are connected to one another by a Common Channel Signaling network 170. It should be noted that the telephone network 130 can comprise additional components (such as a signal transfer point and additional SSPs), which are not shown in
In this preferred embodiment, the server 120 is used to distribute authenticated keys, which are used to authenticate a user for a secured service offered by the server 120 or by another server on the same or different computer network. As used herein, the term “authenticated key” broadly refers to any mechanism that can be used to authenticate a user. An authentication key can be in a form (such as an alpha-numeric string) that allows a user to manually input the key when attempting authentication. An authentication key can take other forms, such as, but not limited to, a cookie for a web browser. A key can also be of such complexity that it is infeasible to transmit other than by automated means.
The operation of this preferred embodiment will now be illustrated in conjunction with
Turning again to the drawings,
The operation of the system will now be illustrated in conjunction with the annotations in
Next, the authentication key is sent through the firewall 390 and is placed on the key distribution server 380 (action 4). The key distribution server 380 then provides the authentication key to the PPP connectivity server 320 through the isolated LAN 370 (action 5). In one embodiment, the PPP connectivity server 320 queries the key distribution server 380 for the authentication key upon an establishment of the communication link between the calling party 300 and the PPP connectivity server 320. In another embodiment, the key distribution server 380 provides the authentication key to the PPP connectivity server 320 upon detection of the establishment of the communication link between calling party 300 and the PPP connectivity server 320. Finally, the PPP connectivity server 320 sends the authentication key to the calling party 300 (action 6), and the SCP 350 removes the authentication key from the key distribution server 380 or marks the authentication key as distributed.
With the authentication key, the calling party 300 can access a secured service offered by the same or different server on the Internet. For example, the calling party 300 can phone a different dial-up server to access a secured service, such as a service that provides the calling party 300 with the ability to turn on/off telecommunication features offered to that calling party 300. In this example, the calling party 300 connects to the connectivity server 320 only once (to receive the authentication key), and then uses the authentication key in a later interaction with a different server.
There are several alternatives that can be used with these preferred embodiments. In the preferred embodiment discussed above, the SCP retrieved an authentication key from a database and sent the key to the key distribution server. In an alternate embodiment, the database merely stores a list of calling line identifiers for which authentication keys exist. In this embodiment, the key distribution server—not the database consulted by the SCP—stores authentication keys. In operation, in response to a query from the SSP, the SCP consults the database to determine whether the calling line identifier is listed as one of the calling line identifiers for which an authentication key exists. If the calling line identifier is listed, the SCP sends an indication to the key distribution server that the authentication key stored in the key distribution server should be sent to the calling party. After the authentication key is sent to the calling party, the authentication key can be removed from the key distribution server or the authentication key can merely be marked as distributed.
It should also be noted that originating or terminating SSPs can be used to send a query to an SCP. Additionally, while the telephone networks were described above as AIN networks, other types of networks can be used. More generally, any suitable type of telecommunication element (e.g., switches, processors) can be used to implement the methods described above. Further, computer-readable media having computer-readable code embodied therein for implementing these methods can be used.
Finally, in the embodiments described above, a telephone network determines an authentication key associated with a calling line identifier and sends the authentication key to a server. In an alternate embodiment, a component other than the telephone network (e.g., a server or other component in a computer network) can store data correlating calling line identifiers and authentication keys, and the same or a different component in the computer network can use this data to determine an authentication key associated with a given calling line identifier. For example, a calling line identifier such as a directory number can be provided to the called party when the called party uses an 800 number or when the called party subscribes to a Caller ID service in an AIN or non-AIN network. The called party can use the directory number to authenticate the caller so that an authentication key is sent only if the directory number is recognized.
It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that it is the following claims, including all equivalents, that are intended to define the spirit and scope of this invention.
The present patent document is a continuation of U.S. patent application Ser. No. 10/038,048, filed Dec. 20, 2001, which is a continuation-in-part of U.S. patent application Ser. No. 09/747,741, filed Dec. 22, 2000, the entirety of which are both hereby incorporated by reference.
Number | Date | Country | |
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Parent | 10038048 | Dec 2001 | US |
Child | 11261296 | Oct 2005 | US |
Number | Date | Country | |
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Parent | 09747741 | Dec 2000 | US |
Child | 10038048 | Dec 2001 | US |