Abstract:
An access arrangement ( 11 ) provides secure access by at least one mobile communications device (12 1 –12 3 ) by first authenticating the device itself, and thereafter authenticating the traffic therefrom. To authenticate the traffic from the mobile communications device, an authentication server ( 24 ) associated with the access arrangement ( 11 ) establishes a Wired Equivalent Privacy (WEP) encryption key for both the access arrangement and the mobile communications device. The authentication server provides the WEP encryption key to the device in connection with a command to cause the device to execute a resident ActiveX control to encrypt traffic with the WEP encryption key. Utilizing the Active X control within the mobile communications device to encrypt traffic with the WEP encryption key provides a simple, easy-to-implement method to achieve secure access.

Description:
TECHNICAL FIELD 
   This invention relates to a technique for enabling a mobile communication device to securely access a wireless Local Area Network (LAN). 
   BACKGROUND ART 
   Presently, providers of data communications services have established wireless Local Area Networks (LANs) (“hot spots”) at publicly accessible facilities, such as rest stops, cafes, and libraries, to allow mobile communication devices to access a private data network or a public data network, such as the Internet, for a fee. Upon entering such a publicly accessible facility, the mobile communication device establishes a communication link, typically over a wireless channel, with an access point (AP) to access to the wireless LAN, and the public or private network therebeyond. Presently, for web browser based authentication, initial validation of the mobile communication device occurs through the use of the secure hypertext transfer protocol (HTTPS) executed by the browser software in the device. However, authentication of the mobile communication device is only one of several factors that affect overall security. Another factor affecting security is traffic authentication. 
   After successful authentication of the mobile communication device, the question remains how can the wireless LAN make sure that the traffic it receives originates from the authenticated mobile communication device and not an unauthorized sender. In practice, the mobile communication device originates IP packets (which can be further broken down to Ethernet frames) without any device identification or signature. Thus, from the perspective of the wireless LAN, incoming IP packets from an authorized sender look exactly the same as those from an unauthorized sender. Hence, the wireless LAN has no way to distinguish between traffic from an authorized mobile communication device and from a hacker who has managed to circumvent the initial authentication process. 
   Thus, there is need for a technique that enables a mobile communications device to securely access a wireless LAN so as to overcome the aforementioned disadvantage of the prior art. 
   BRIEF SUMMARY OF THE INVENTION 
   Briefly, in accordance with the present principles, there is provided a method for enabling a mobile communications device to securely access a wireless LAN. The method commences upon receipt in the wireless LAN of an access request from the mobile communications device. Thereafter, the wireless LAN authenticates the mobile communications device in accordance with authentication information received from the device. After authenticating the mobile communications device, the wireless LAN notifies the mobile communications device to invoke an executable program to enable a privacy key, typically a Wired Equivalent Privacy (WEP) encryption key. In practice, the executable program typically comprises an ActiveX program downloaded to the mobile communications device upon successful authentication. In addition to invoking the executable program in the mobile communications device to enable the WEP encryption key, the wireless LAN invokes the WEP for itself, thus enabling secure communications with the mobile communications device. Most present day browser software programs found in mobile communication device support ActiveX controls, so using such a feature to invoke the WEP encryption key affords a simple technique for authenticating mobile communication device traffic to assure secure wireless LAN access. In case ActiveX control is not supported by the browser on the mobile device, other techniques such as plug-ins can be employed. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  illustrates a block schematic diagram of a wireless LAN for implementing the method of the present principles for establishing a business relationship with a Billing Agent; and 
       FIG. 2  illustrates a ladder diagram depicting the communications occurring between the wireless LAN and the mobile communications device over time to enable secure wireless LAN access. 
   

   DETAILED DESCRIPTION 
     FIG. 1  depicts a block schematic diagram of a communications network  10  that includes an access arrangement  11  for enabling at least one mobile communication device, and preferably a plurality of mobile communication devices (e.g., mobile communication devices  12   1 ,  12   2 , and  12   3 ) to securely access either a private data network  14  or a public data network  16 , such as the Internet. In a preferred embodiment, the mobile communication device  12   1 , comprises a lap top computer, whereas the mobile communication device  12   2  comprises a Personal Data Assistant, and the mobile communication device  12   3  comprises a wireless handset. 
   The access arrangement  11  of  FIG. 1  includes at least one, and preferably, a plurality of access points (APs), best exemplified by APs  18   1 – 18   4 , via which the mobile communication devices  12   1 ,  12   2  and  12   3  each access a wireless Local Area Network (LAN)  20 . Although shown separately, the APs  18   1 – 18   4  comprise part of the wireless LAN  20 . A gateway  22  provides a communication path between the wireless LAN  20  and the private and public networks  14  and  16 , respectively. In the illustrated embodiment, each AP, such as AP  18   1 , includes a wireless transceiver (not shown) for exchanging radio frequency signals with a radio transceiver (not shown) within each mobile communication device. To this end, each of the APs  18   1 – 18   4  employs one or more well-known wireless data exchange protocol, such as the “HiperLan 2” or IEEE 802.11 protocols. Indeed, different APs could employ different wireless protocols to accommodate different mobile communication devices. 
   The gateway  22  provides a link between the wireless LAN  20  and an authentication server  24 . In practice, the authentication server  24  takes the form of a database system containing information about potential users to enable each of the APs  18   1 – 18   4  to authenticate a mobile communications device seeking access. Rather than exist as a separate stand-alone entity, the authentication server  24  could exist within the wireless LAN  20 . A billing agent  26  has a connection with the wireless LAN  20  through the gateway  22  to facilitate billing of each mobile communication device accessing the wireless LAN. As with the authentication server  24 , the functionality of the billing agent  26  could exist within the wireless LAN  20 . 
   In accordance with the present principles, there is provided a technique for enabling each mobile communication device, such as each of devices  12   1 – 12   3 , to securely access the wireless LAN  20  to afford authentication of both the device itself, as well as the traffic that emanates therefrom. The authentication technique of the present principles can best be understood by reference to  FIG. 2 , which depicts the sequence of communications that occurs over time among a mobile communication device, say device  12   1 , an AP, say AP  18   1 , and the authentication server  24 . To initiate secure access, the mobile communications device  12   1  transmits a request for access to the AP  18   1  during step  100  of  FIG. 2 . In practice, the mobile communications device  12   1  initiates the access request by way of a HTTPS access demand launched by a browser software program (not shown) executed by the device. In response to the access request, the AP  18   1  redirects the browser software in the mobile communications device to a local welcome page on the AP during step  102 . 
   Following step  102 , the mobile communications device  12   1 , of  FIG. 1  initiates authentication by querying the AP  18   1 , of  FIG. 1  for the identity of the appropriate authentication server during step  104  of  FIG. 2 . In response, the AP  18   1  determines the identity of appropriate authentication server (e.g., server  24 ) during step  106  of  FIG. 2  and then directs the browser software in the mobile communications device  12   1  to that server via an HTTP command during step  108  of  FIG. 2 . Having now received the identity of the authentication server  24  during step  108 , the mobile communications device  12   1  then sends its user credentials to the server during step  110  of  FIG. 2 . 
   Upon receipt of the user credentials from the mobile communications device  12   1 , the authentication server  24  makes a determination whether the mobile communications device constitutes a valid user during step  112 . If so, then the authentication server  24  replies to the mobile communications device  12   1  during step  114  with a Wired Equivalent Privacy (WEP) encryption key which the device invokes via an ActiveX command of an ActiveX control though the device browser software. Simply speaking, an ActiveX control is essentially an executable program that can be embedded inside a web page. Many software browser programs, such Microsoft Internet Explorer have the capability of displaying such web pages and invoking the embedded ActiveX controls, which can be downloaded from a remote server (e.g., the authentication server  24 ). The execution of the ActiveX controls are restricted by the security mechanisms built into the browser software. In practice, most browser programs have several different selectable security levels. At the lowest level, any ActiveX control from the web can be invoked without restriction. In the highest level, no ActiveX control can be invoked from the browser software. 
   Normally, the security level is set to medium, in which case only those ActiveX controls that have digital signatures can be invoked. For such ActiveX control, the browser software first checks the validity of the signature before invoking the ActiveX control to make sure that the following conditions exist: (1) the source of the ActiveX control can be traced, and (2), the ActiveX control has not been altered by anyone else other than the entity who signed it. In the illustrated embodiment, the authentication server  24  uses ActiveX control to deliver and set the WEP key on the mobile communications device  12   1  after the device is authenticated. The ActiveX control is very simple and its only function is to set the key on the mobile communications device  12   1  by providing the device a web page with the embedded ActiveX control, which is signed by the authentication server  24  following device authentication. 
   After providing the mobile communications device  12   1  with the WEP session key during step  114 , the authentication server  24  provides a corresponding WEP session key to the AP  18   1  during step  116 . Next, the mobile communications device  12   1  enables WEP during step  118  of  FIG. 2  and then commences the transmission of WEP-encrypted traffic to the AP  18   1  during step  120  whereupon the AP will de-encrypt the data in accordance with its WEP session key. 
   The above-identified method for enabling secure wireless LAN access will work seamlessly for the majority of mobile communications devices since most devices employ browser software that support ActiveX controls, and the security level of the browser software in most devices is generally set to medium. For those mobile communications devices whose browser software is currently set with highest level of security, a request will be sent to the device to ask the user to temporarily alter the security setting for the web browser software to medium. For those mobile communication devices that do not employ browser software capable of supporting ActiveX controls, a browser software plug-in can be used. If the AP  18   1  detects that the browser software in the mobile communications device  12   1  seeking access does not support ActiveX control, the user of the mobile communications device  12   1  will be prompted to download and install a small plug-in. The functionality of the plug-is essentially the same as the key-setting function of the ActiveX control. Once the plug-in is installed in the mobile communications device  12   1 , the authentication server  24  can set the WEP key on the mobile communications device by packaging the WEP key in a special file that invokes the plug-in. In turn, the plug-in reads the key WEP file and sets the key in the mobile communications device  12   1 . 
   For practical purposes, the WEP key setting ActiveX control should be parameterized. In other words, the ActiveX control should take the WEP key as a parameter. In this way, the authentication server  24  only needs to maintain a single compiled ActiveX control and use it for different sessions by supplying different parameters to requesting mobile communications devices. Otherwise, the authentication server  24  would have to build the WEP key inside the ActiveX control, i.e. build a different ActiveX control for each session, an inefficient process. 
   Under some circumstances, the parameterized approach could be prone to a security attack. Potentially a hacker knowing about the ActiveX control could compose a web page that invokes this ActiveX control with an arbitrary parameter. If the mobile communications device encounters such a web page, the WEP key on the device could be set incorrectly. No great harm will occur but such an attack could inconvenience the mobile communications device user because of the incorrectly set WEP key. A similar problem can exist when the mobile communications device  12   1  does not support ActiveX control and must download an appropriate plug-in. A hacker could compose a web page with the special file type that invokes the WEP key-setting plug-in on the mobile communications device  12   1 . Again, no great harm will occur other than having the WEP key set incorrectly on the mobile communications device. 
   This type of security attack can be thwarted by the use of a server signature. In other words, the authentication server  24  not only signs the ActiveX control, but also signs the parameters. Further, to prevent a replay attack in which a hacker stores a previously used parameter to misconfigure the key on the user&#39;s device, the signed key will include an embedded time stamp. This process works in the following manner. The authentication request submitted by the mobile communications device  12   1  to the authentication server  24  contains a script (e.g. a Javascript) that includes the local time kept by the device. The mobile communications device  12   1  sends this information to the authentication server  24 , typically as a hidden field in the HTML form on the page. In response, the authentication server  24  generates the encrypted WEP key, concatenates it with the local time of the mobile communications device  12   1  and signs the result with the server&#39;s private key. 
   The authentication server  24  sends the signed string as the parameter to the ActiveX control to the mobile communications device  12   1  (or in the case of plug-in, the file for the plug-in). The ActiveX control has the server&#39;s public key built-in. Upon execution at the mobile communications device  12   1 , the ActiveX control checks the parameter to make sure: (1) the parameter is indeed from the authentication server  24 , and (2) the current local time and the local time in the parameter reasonably match to prevent a replay attack. The key is only set when the check passes. 
   For the plug-in, the signed string is placed in the file having the special extension for invoking the plug-in. Because multiple servers could employ the same plug-in, the plug in does not have a particular server&#39;s public key built in. Thus, in addition to the signed string mentioned above, the file also contains the certificate of the server. When the file is delivered to the mobile communications device  12   1  and the plug-in is invoked, the plug-in examines the server&#39;s certificate in the file, obtains a valid server public key and verifies the signed string as described above. 
   The foregoing describes a technique for enabling secure access to a wireless LAN.