Patent Abstract:
In mobile IP networks, when a mobile node (MN) moves from one cell to another, handover occurs. The result of the handover is that the MN connects to the network through a new access router (AR). The handover may occur between access routers of the same or different administrative domains. In all cases, the information related to the mobile node has to be transferred from the old AR to the new AR in order to minimize the effect of the change of access routers.

Full Description:
[0001]    This is a Divisional of application Ser. No. 10/309,366, filed Dec. 2, 2002, which claims priority of Provisional Patent Application No. 60/336,937, filed Dec. 3, 2001, the contents of which are incorporated herein. 
     
    
     BACKGROUND 
       [0002]    In mobile IP networks, when a mobile node (MN) moves from one cell to another, handover occurs. The result of the handover is that the MN connects to the network through a new access router (AR). The handover may occur between access routers of the same or different administrative domains. In all cases, the information related to the mobile node has to be transferred from the old AR to the new AR in order to minimize the effect of the change of access routers. This is the so-called context transfer (see H. Syed et al, “General Requirements for a Context Transfer Framework,” draft-ietf-seamoby-ct-reqs-alpha05.txt, IETF Internet Draft, May 2001). We propose a policy-based approach that is efficient, secure and does not require significant additional functionalities being built into access routers. 
         [0003]    Current or proposed solutions are based on moving the complete intelligence to the network elements, i.e., access routers. Each access router must discover candidate access routers for possible handover, select the target access router for actual handover based on the capabilities of the mobile node, authenticate the target access router and finally perform the context transfer. Specifically, each access router performs the following functions: 
         [0004]    1. Contacting the respective Home agent server 
         [0005]    2. Contacting the Home AAA server 
         [0006]    3. Interpreting the static subscription profile of the mobile node 
         [0007]    4. Authenticating and authorizing the neighboring access routers 
         [0008]    5. Interpreting the static capability of the neighboring access routers (and/or) 
         [0009]    6. Moving the static capacity of the mobile node to the access routers (and/or) 
         [0010]    7. Performing some pre-context activities before the actual context transfer 
         [0011]    8. Finally transferring the context to the new access router 
         [0012]    These functions are in addition to the main responsibilities of an access router, i.e., to route IP packets based on subscriber information and to perform metering and monitoring for charging and management purposes. Hence, the above functions may require a radical change in the current Internet infrastructure. The following are the potential shortcomings: 
         [0013]    1. Currently there is no common mechanism for two access routers to exchange information across two autonomous systems (AS). 
         [0014]    2. For security reasons, network operators do not want to expose the capabilities or capacity of their access routers. If one of the router is compromised the whole system is likely to get compromised. Yet current solutions require routers to expose their capabilities to other routers in same or different domains 
         [0015]    3. Moving the intelligence to the access router is a security issue. Control and update distributed information is always a potential problem. In strictly protected networks such as Telecom networks, this may be less important. But IP networks are not as easy to protect as Telecom networks. 
         [0016]    4. There are no automatic schemes where routers can authenticate each other. They may relay on public key based mechanism but it&#39;s a along way to go as the public key mechanism may take time into effect. 
         [0017]    5. The router selection rules or algorithms are installed on all access routers or Mobile Nodes. This may increase the cost of both access routers and mobile nodes and impact router performance. In addition, a simple change of the selection rules requires updating on all routers or mobile nodes. 
         [0018]    The above-mentioned references are exemplary only and are not meant to be limiting in respect to the resources and/or technologies available to those skilled in the art. 
       SUMMARY 
       [0019]    The proposals in this invention comprise two aspects. First, we propose a policy based mechanism to select a possible target (new) access router for context transfer. Second, we describe two context transfer sequences for intra/inter domain handovers. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0020]    The disclosed inventions will be described with reference to the accompanying drawings, which show important sample embodiments of the invention, wherein: 
           [0021]      FIG. 1  is a reference system for transferring context of a mobile node between autonomous systems; 
           [0022]      FIG. 2  shows a context transfer message flow, according to an embodiment; and 
           [0023]      FIG. 3  shows a proactive handover embodiment. 
       
    
    
     DETAILED DESCRIPTION 
       [0024]    An embodiment of the invention may perform policy based target router selection and context transfer. Embodiments may provide the following benefits: 
         [0025]    1. Balance the functionalities between policy servers and access routers. 
         [0026]    2. Centralize the critical information for admission control and operation of the network in the policy server. This makes updating and protecting the policy rules easier. 
         [0027]    3. Routers do not need to expose and discover the capabilities of other routers because this information is readily available at policy servers. This effectively reduces the amount of messages exchanged over the network, saving valuable bandwidth. 
         [0028]    4. Access routers are freed from target router selection process and most of context transfer process. Hence they can focus on performing their main duty, i.e., route internet protocol packets. 
         [0029]    5. Access routers need not execute proxy application if their neighbors are running different technology. 
         [0030]    6. In most wireless networks, the critical resource is radio spectrum. In the traditional mechanism where handover occurs prior to authorization, radio resources are allocated to the MN prior to authorization. If the MN failed the authentication and authorization process, then such radio resources have to be revoked. This could have repercussions such as the blocking of a legitimate user that could be handed over to this network otherwise. By performing an authorization prior to handover, we avoid this problem of blind radio resource allocation, thereby conserving use of the radio spectrum and associated radio resources. 
         [0031]    7. Receiver driven approach for target selection helps in reducing denial of service attacks. 
         [0032]    A possible disadvantage is that the policy server may become a single point of failure. But proper network planning and incorporating Rservpool architecture for policy server can strengthen the availability and reliability of the policy server. 
         [0033]      FIG. 1  shows the reference architecture for the context transfer framework and the target access router selection process. Access routers, e.g. source access router (AR)  101  and destination access router  123  are policy targets. On boot up, the access routers may report their capabilities (QoS, Security etc) to a policy server  105 . The policy server (PS 1 )  105  then downloads the corresponding policy to the AR  101  according to the reported capabilities. Therefore the policy server  105  has all the information about an AR  101  capabilities in the administrative domain  110 . In addition the policy server  105  can retrieve information relating to the base station  107  from the database of network management systems. The information includes, for example, which access router a base station  107  is connected to. 
         [0034]    In  FIG. 1 , Mobile Node (MN)  151  is currently in Autonomous System AS 1   110  and is communicating with a server in a core network  140 . The static capabilities of the MN  151  are stored in a AAA server, e.g. AAA1 server  109 . The policy server can retrieve this information from the AAA server of the MN home network. In the following, we describe the problem of inter domain handover which is more complicated than intra domain handovers. 
         [0035]    For example, when the MN  151  is in the AS 1   110 , the static capabilities of the MN  115  are retrieved by PS 1   105  from AAA1 server  109  and dynamic capabilities (or negotiated profiles) are kept with the access router AR 1   107  that is currently serving the MN  151 . When the MN  151  moves toward Autonomous System (AS 2 )  120 , it receives identification information on a broadcast channel which may contain link layer information of a second base station (BS 2 )  127  or IP address of AR 2   120  or Autonomous System number associating some link local address or any combination information. MN  151  forwards the information to AR 1   101 . 
         [0036]    An embodiment includes steps. The first step is the access router selection process where policy servers compute a list of possible access routers that may serve the MN  151  and the MN  151  is informed of this list by the policy server in its own domain. The second step involves the actual context transfer. Details of the two steps are described in the following subsections. 
         [0037]    7.1 Selection of Access Routers Prior to Handover 
         [0038]    In this selection process, the policy server in the same domain as the candidate access routers computes the selection process. 
         [0039]    When the MN receives new identifiers from more than one base station through the broadcast channel, the MN forwards the information to the AR currently serving it, e.g. AR 1   101 . The access router forwards it to the policy server, e.g. PS 1   105 . The minimal information which the policy server  105  expects is either the link layer identifier or Autonomous System (AS) number and link layer identifier. 
         [0040]    1. If PS 1   105  receives only link layer identifier, it checks first with the policy database to see whether that is simply an intra domain handover. If it is not an intra domain handover, PS 1   105  checks with the neighboring AS defined in the policy database and forwards to their neighboring policy server. 
         [0041]    2. (or) It would be faster if the AS number is also sent in the broadcast channel by each base station this eliminates lots of processing. If AS number is sent then the policy server, e.g. AR 1   101 , forwards the information to the respective policy server, e.g. PS 2   126 , along with the MN static capabilities (which it retrieved from AAA1 server  109 ). 
         [0042]    3. After receiving the information, the PS 2   125  determines whether AS 2   120  can potentially serve the MN  151 . If yes, PS 2   125  further computes the candidate access routers that will be able to serve the MN  151 . PS 2   129  then returns the computed access routers to PS 1   105  (this is totally dependent on the topology of the AS). An algorithm for selecting the access routers is described in the next subsection. If the access router cannot serve the MN, PS 2   125  simply sends a negative acknowledgement to PS 1   105 . 
         [0043]    If MN  151  has forwarded more than one access system identifiers to the AR 1   101 , the PS 1   105  performs the above steps for each access system. Finally PS 1   105  sends a message to MN  151  informing all the possible (or authorized) ARs that may server the MN  151 . 
         [0044]    7.1.1 An Algorithm for AR Selection within an AS 
         [0045]    An embodiment of an AR selection algorithm may be used by a policy server. It is based on a sequence of elimination processes. 
         [0046]    Given the set of reachable access routers for the mobile node 
         [0047]    1. Eliminate those routers that cannot meet the mobile node&#39;s static capabilities. 
         [0048]    2. Eliminate those routers whose traffic load is above a given threshold; 
         [0049]    3. Use other operator defined rules to eliminate more routers. 
         [0050]    4. Finally, when all rules are executed and if several routers survived the elimination processes forward all of them to the initiating PS. 
         [0051]    The order of the rules may be changed on the policy server. In general, a rule that is able to eliminate more routers should be evaluated before those that eliminate fewer routers. Some times it may be difficult to predict which rule will eliminate more routers. The insight can be gained with experience and a careful analysis of log data on policy servers. 
         [0052]    There is no need to reserve any resource at AR&#39;s during this process. PS can pre-authorize MN. The initiating PS after receiving the list of possible AR&#39;s has to periodically inform the MN&#39;s presence in their network. 
         [0053]    The second step in the above selection algorithm requires the policy server to have the knowledge of traffic load on the access routers. There are two possible ways a policy server may obtain the current load of access routers: 
         [0054]    If the policy server also performs admission controls, it knows the load on those routers naturally. If there is an admission control server, for example a bandwidth broker, the policy server can do a simple query of the server to get the load situation on those routers. 
         [0055]    Some networks may have no centralized admission control. For example, a network may operate on constrained routing where unused network resources are advertised globally within an administrative domain and each router makes admission control decision based on the advertised information. In this case, the policy server simply listens to the advertisement to know the unused resources on those routers. It then uses that information as an input to the above router selection algorithm. 
         [0056]    7.2 Context Transfer Protocol 
         [0057]    When a MN is roaming in a network, it may receive signals from adjacent base stations. The MN can perform two types of handovers namely reactive and proactive. In the reactive case, the MN informs the new access router to pickup its context from the old access router. In the proactive case, the MN forwards the new access router&#39;s identities to the old access router and informs the old access router to push the context to the new access router. 
         [0058]    Preconditions 
         [0059]    1. MN is initially in AS 2  and is moving towards AS 1 . MN picks up more than one base station signals. With the target access router selection process described above, the MN is aware of the possible access routers who can satisfy its capabilities. 
         [0060]    2. During the target access router selection process, each possible AS domain has pre-authorized the MN. Hence, context transfer is just a simple relocation of state information 
         [0061]      FIG. 2  shows a context transfer message flow. 
         [0062]    1. MN  251  that was roaming in the AS 2   220  moves towards AS 1   210  and starts receiving the base station signal. MN  251  forwards the AS 2 :AR 2  identity to the AR 1 , as a identity packet  261 . 
         [0063]    2. AR 1   201  requests  262  PS 1   205  to prepare the context transfer request. 
         [0064]    3. PS 1   205  forwards the MN context request to the AS 2   220  in a forwarded packet  263 . 
         [0065]    4. AR 2   223  sends the context related to the MN in a message  264  to PS 2   225 . 
         [0066]    5. PS 2   225  adds to the context received from AS 2  the static context about MN that is available at PS 2   225 . In addition, PS 2   225  may collect other dynamic context from other network elements. For example, MN  251  may have a security context associated with a gateway in AS 2   220 . PS 2   225  sends all these static and dynamic contexts to AR 1   201  in a first cross-network message  265 . 
         [0067]    6. AR 1   201  extracts the context relevant to AR 1   201  and forwards the rest of the context  266  to PS 1 . 
         [0068]    7. PS 1   205  extracts the static context and forwards the rest of the context  167  to related network elements, e.g., a security gateway that will reconstruct the security context. PS 1   205  sends a context transfer complete message to AR 2   223  in a second cross-network message  267 . 
         [0069]    8. AR 2   223  forwards the context transfer complete message  268  to PS 2   225  and finally context may be removed from AS 2   223 . 
         [0070]    The policy server may be totally kept in private address space due to security reasons and may not be accessible or visible from outside the autonomous system. 
         [0071]      FIG. 3  shows a proactive handover embodiment. 
         [0072]    Preconditions: 
         [0073]    1. MN  351  is initially in the AS 1   310  and is moving towards AS 2   320 . MN  351  picks up more than one base station signals. With the target access router selection process described above, the MN  351  is aware of the possible access routers who can satisfy its capabilities. 
         [0074]    2. During the target access router selection process, each possible AS domain has pre-authorized the MN  351 . Hence, context transfer is just a simple relocation of state information. 
         [0075]    Context Transfer Message Flow: 
         [0076]    1. MN  351  that is currently roaming in AS 1   310  decides to move to AS 2   320  because the signal from AS 2   320  is stronger than that from AS 1   310 . Under this situation MN  351  forwards  361  the AS 2 :AR 2  identity to the AR 1   301  and requests it to start the context transfer. 
         [0077]    2. AR 1   301  forwards the context to PS 1   305  and informs PS 1   305  to forward  362  the context to AR 2   323 . 
         [0078]    3. PS 1   305  adds to the context received from AR 1   301  the static context about MN  351  that is available at PS 1   305 . In addition, PS 1   305  may collect other dynamic context from other network elements. For example, MN  351  may have a security context associated with a gateway. PS 1   305  sends  363  all these static and dynamic contexts to AR 2   323 . 
         [0079]    4. AR 2   323  extracts the context relevant to AR 2   323  and forwards  364  the rest of the context to PS 2   329 . 
         [0080]    5. PS 2   329  extracts the static context and forwards the rest of the context to related network elements, e.g., a security gateway that will reconstruct the security context. PS 2   329  sends  365  a context transfer complete message to AR 1   301 . 
         [0081]    6. AR 1   301  forwards  366  the context transfer complete message to PS 1   305  and finally context is removed from AS 1   310 . 
         [0082]    Although described in the context of particular embodiments, it will be apparent to those skilled in the art that a number of modifications and various changes to these teachings may occur. Thus, while the invention has been particularly shown and described with respect to one or more preferred embodiments thereof, it will be understood by those skilled in the art that certain modifications or changes, in form and shape, may be made therein without departing from the scope and spirit of the invention as set forth above and claimed hereafter.

Technology Classification (CPC): 7