Abstract:
Information collecting system wherein at least an Application Service Provider (ASP) provides services to a user through an Internet network and wherein there are at least an access network to which is connected the user and an Internet Service Provider (ISP) network connected to each access network by a RADIUS client, the Internet network being connected to the ISP network by a proxy. This system comprises a RADIUS Client Agent (RCA) connected to the ISP network and adapted to collect information about parameters of the connection of the user to the system, and at least a Provisioning Proxy Agent (PPA) adapted to receive the information from the RCA and to add this information in the request sent by the user to the ASP.

Description:
TECHNICAL FIELD  
       [0001]     The present invention generally relates to the access of applications provided in an IP network such as Internet and more particularly relates to an information collecting system for providing connection information to an application in an IP Network.  
       BACKGROUND  
       [0002]     The access of users to internet services through a private or public IP network, such as a Public Switched Telephone Network (PSTN), a General Packet Radio Service (GPRS), etc., must be controlled for reason of security and to avoid useless load of network lines. Companies providing remote access to their servers, such as web content servers, often share the services of authentication using a Remote Access dial-in User Services (RADIUS) server to control remote user connections. The protocol for authentication and authorization is defined in the Request For Comment (RFC) documents RFC 2865 and the RADIUS protocol for accounting is defined in the RFC 2866. The RADIUS server performs authentication of users and checks that the remote users are authorized to be connected to the network, in order to access the content servers through the IP network. The RADIUS server is also in charge of collecting accurate accounting of connection time so that the users may be billed correctly by the content servers.  
         [0003]     Users can connect to an IP Network in numerous ways, including through a PSTN, GPRS, digital subscriber lines (xDSL), and wireless network WI-FI. Such a connection is made by means of access servers acting as gateways which are installed at the periphery of the IP network. The access server establishes a user session using the services of a RADIUS server. The RADIUS server performs the authentication, checking the password received from a user and provides an authorization to connect according to the network capacity. The access server sends an IP address to the user and acts as a router to the IP servers once a session is established. When a session is established, it asks the RADIUS server to start the accounting for this session. When the user is disconnected by the network, the access server asks the RADIUS server to stop the accounting for this session. One RADIUS server can collect accounting information for a set of access servers. Using the accounting information, a bill for the connection to IP content servers is created and sent to the user.  
         [0004]     The application service providers (ASP) have to adapt their services according to the type of access network used by their customers. Thus, a customer can now have access to video services through GPRS, WI-FI, PSTN or a leased line and the connection parameters used by the ASP will be different according to the access network being used. However, these connection parameters, such as identification, speed or bandwidth are not provided today at the application level. This could be detrimental for some specific services such as media distribution. In some cases, this needed information can be retrieved by the web application from the RADIUS server session table using the client IP address. Unfortunately, these solutions do not work if there is a proxy or a firewall in mode proxy between the user and the web application.  
         [0005]     Another solution consists in requesting some information from the user, such as the quality of the video being received according to the speed or bandwidth. But, in most cases, the user is not able to answer or is unable to determine the speed negotiated by the modem. Furthermore, the RADIUS server has no open interface to provide connection information in real time to third party application (proxy, application server . . . ).  
       SUMMARY OF THE INVENTION  
       [0006]     Accordingly, an object of the invention is to provide a system for collecting information on connection characteristics for application service providers in order to offer a good quality of service to their customers.  
         [0007]     Another object of the invention is to provide information enabling functions such as automatic recognition of a user in order to provide automatic logon to applications.  
         [0008]     The invention therefore relates to an information collecting system wherein at least an Application Service Provider (ASP) provides services to a user through an Internet network and wherein there are at least an Internet Service Provider controlling an access network to which is connected the user and an Internet Service Provider (ISP) network connected to each access network, the Internet network being connected to the ISP network by a proxy. Such a system comprises a Remote Access Dial-in User Server (RADIUS) Client Agent (RCA) connected to the ISP network and adapted to collect information about parameters of the connection of the user to the system, and at least a Provisioning Proxy Agent (PPA) adapted to receive the information from the RCA and to add this information in a request sent by the user to the ASP.  
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0009]     The above and other objects, features and advantages of the invention will be better understood by reading the following more particular description of the invention in conjunction with the accompanying drawings wherein:  
         [0010]      FIG. 1  is a block-diagram representing a system implementing the invention; and  
         [0011]      FIG. 2  is a time diagram representing the steps realized for implementing the system illustrated in  FIG. 1 . 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0012]     A system according to the invention illustrated in  FIG. 1  includes one or several access networks (e.g., a PSTN network  10  and a GPRS network  12 ) to which are connected users, such as user  14 . Each access network  10 ,  12  is connected to an Internet Service Provider (ISP) network  16  (e.g., a LAN) by means of RADIUS (Remote Access Dial-in User Server) clients, such as RADIUS client  18  connected to PSTN  10  or RADIUS client  20  connected to GPRS  12 . It must be noted that other access networks could be used such as xDSL or a WI-FI network.  
         [0013]     The ISP network  16  is connected by means of a proxy  22  to the Internet network  24  enabling each user, such as user  14 , to gain access to services provided by a plurality of Application Service Providers (ASP)  26 ,  28  or  30 .  
         [0014]     By using a RADIUS protocol, the request of authentication and authorization of a user requesting services to the ISP is sent to a RADIUS server  32  connected to the ISP network  16  by the intermediary of a proxy RADIUS server  34 , which receives the request directly from the RADIUS client  18  or  20 .  
         [0015]     The application service providers (ASP) have to adapt their services according to the type of access network used by the customer. Thus, the parameters to be used to access the video services will be different according to whether a GPRS, PSTN or WI-FI network is used. For this, the ASP needs information about the type of connectivity being used, such as identification, speed and bandwidth. Unfortunately, this information is not provided at the application level.  
         [0016]     The solution to the above problem consists in taking advantage of the RADIUS protocol used to authenticate the user by the RADIUS server and to authorize the access. After the access has been authorized, the RADIUS server  32  sends a response (Access-accept) to the RADIUS client  18  or  20 . The RADIUS client  18  or  20  then sends an accounting start to start the session and an accounting stop at the end of the session. Thus, the RADIUS protocol allows triggering a RADIUS client Agent (RCA)  36  responsible to gather and send information related to the user and the connection. Such information is then sent by the RCA  36  to a Provisioning Proxy Agent (PPA)  38  which is, in a preferred embodiment, incorporated in the proxy server  22 . The PPA  38  configures the proxy server  22  to add the information in the user&#39;s request. The proxy can use this information to build a cookie or to add an HTTP header in the HTTP requests to the destination of the application. It must be noted that the RCA  36  can receive information from several RADIUS clients but may also gather information directly from the modems by using Simple Network Management Protocol (SNMP) commands.  
         [0017]     In reference to  FIG. 2 , the process implemented in the invention begins when an Access Request is sent from the RADIUS client to the RADIUS proxy. This request, which includes the logon and password of the user, is then forwarded to the RADIUS server which returns an Access Accept including the IP address of the user of this session. All the information exchanged by using the RADIUS protocol is intercepted by the RADIUS proxy, which thus keeps track of the user name, the password, the RADIUS client address, and the RADIUS client port. Note that the IP address could be allocated by the RADIUS client.  
         [0018]     After receiving the acceptation of the session, the RADIUS client sends an Accounting start to the RADIUS server, which includes the logon/password of the user, the port number, the type of connection and the IP address of the user. The RADIUS server returns an Accounting response. In the same way as for the Access request, the RADIUS proxy intercepts the Accounting start and forwards a Start message including the RADIUS client IP address and the port to the RCA. Optionally, the RCA can send a SNMP command to the RADIUS client in order to retrieve some information and principally the speed negotiated during the connection by the modem for the port number being used. All the information consolidated by the RCA is forwarded in a Start message to the PPA, which is responsible to set up the proxy server to either set a cookie, add HTTP header information or an URL extension containing the information needed by the destination application.  
         [0019]     At the end of the session, the RADIUS client sends an Accounting stop containing the same information as the Accounting start to the RADIUS server, which returns an Accounting response to the RADIUS client. In the same way as for the Accounting start, the Accounting stop and its response are intercepted by the RADIUS proxy. The RADIUS proxy forwards a Stop message to the RCA, which also sends a Stop message to the PPA indicating thereto that the session is ended for this IP address.  
         [0020]     When the RCA forwards the Start message to the PPA, the PPA stores the received information in a session table containing three columns defining the session identifier (the user IP address), the parameter name and the parameter value. Such a session table could be the following:  
                                               PARAMETER       USER ID ADDRESS   PARAMETER NAME   VALUE                   XX.YY.ZZ.WW   Login   User1       XX.YY.ZZ.WW   Password   User1 psswd       XX.YY.ZZ.WW   Connection-type   GPRS       XX.YY.ZZ.WW   Connection speed   46K       XX.YY.ZZ.WW   Priority level   3                  
 
         [0021]     All entries corresponding to an IP address are removed from the session table on reception of a Stop message sent by the RCA as described previously. Note that, further to the Start message which adds entries into the session table and the Stop message which deletes entries from the session table, some entries can be updated in case of modification of the session characteristics by an Update message received from the RCA.  
         [0022]     An RCA needs to know which PPA has to be warned of start, stop or change for a given set of connections. A PPA associated with a particular proxy server has to register itself to the RCA. For this, the PPA gives to the RCA the filter to identify the user session for which the RCA must propagate the session information. The filter is useful for limiting the traffic between the RCA and the PPA. Many times, the incoming traffic is divided between several proxies. This division may be based on different mechanisms as those proposed for the PPA filter. Therefore, defining a PPA filter which matches the traffic division between proxies allows optimization of the traffic between the RCA and the PPAs. In most cases, a PPA will not receive information about a connection that will flow to another proxy than the one on which the PPA is attached.  
         [0023]     The filter may be one of the following: a range of IP addresses, a Realm, a RADIUS client IP address, or a called number (often associated with a Realm). Upon reception of a registration message from a PPA, the RCA builds or updates a table. Each row of the table represents a filter for a given PPA. Thus, when a Start message is received by the RCA, the RCA can identify all the rows for which the filter matches the session parameters. An example of such a table is as follow:  
                                                   PPA   PPA                       IP@   port   lowIP@   highIP@   Realm   nasIP@                   9.100.50.10   10041   9.100.100.1    9.100.100.90    —   —       9.100.50.10   10041   9.100.100.200   9.100.100.255   —   —       9.100.50.20   10067   —   —   lagaude.ibm.com   —       9.100.50.20   10067   —   —   raleigh.ibm.com   —       9.100.50.30   10041   —   —   —   9.100.10.10                  
 
         [0024]     After the connection phase described in reference to  FIG. 2 , the proxy receives HTTP requests from the users. Each HTTP request may be transformed to pass parameters to the applications. For this, the PPA can build a table associated with each application as follows:  
                                               Configfuration       ASP Base URL   Proxy Plug in   properties                   Http://host.name/dir   Standard HTTP Headers   HTTP Headers name               and presence       Http://host2.name/dir2   Custom ASP2 plugin   Custom plugin               parameters                  
 
         [0025]     For each ASP URL, this table gives the Plug-in to be called by the proxy when receiving a request for this ASP. Such a Plug-in may be the standard HTTP headers plug-in which adds the session parameters as HTTP headers. These parameters may be the logon user and password. This allows, in particular, to match all applications working with basic HTTP authentication (HTTP Authentication: Basic and Digest Access Authentication, RFC 2617). The Plug-in may also be a custom ASP Plug-in which may build the information inside cookies, for instance. The last column of the table contains the configuration parameters for this ASP. In case of the “standard HTTP headers” Plug-in, the configuration parameters define what session parameters are to be included in the HTTP request (e.g., The user ID and the password) and the names of the HTTP header which holds the session parameters to be included. Note that this application table is created by the administrator depending on the application available. It is updated by the administrator each time an application is added or suppressed.  
         [0026]     Naturally, in order to satisfy local and specific requirements, a person skilled in the art may apply to the solution described above many modifications and alterations all of which, however, are included within the scope of protection of the invention as defined by the following claims.