Abstract:
The invention proposes a system for providing mobility to a terminal through at least two different mobility protocols, wherein a mobility gateway and a terminal share a common mobility session, said common mobility session can be updated through any of the said different mobility protocols, and each mobility protocol provides information to the terminal related to all other mobility protocol during a registration. The invention also proposes a corresponding gateway, a terminal and method.

Description:
BACKGROUND OF THE INVENTION 
       [0001]    1. Field of the Invention 
         [0002]    The invention relates to network control node, a terminal and a method for controlling different types of connection sessions. 
         [0003]    2. Description of the Related Art 
         [0004]    The invention relates to multi-access and mobility. 3GPP is now discussing various way to implement MA (Mobile Access) mobility. 
         [0005]    Currently, there are a number of problems is using many Mobility solutions:
       Each mobility solution has its own gateway. Traffic should typically go through many gateway (e.g. GGSN and HA).   Each mobility solution is using some kind of tunnelling. Having many tunnelling is not optimal, especially over cellular access.   Each mobility solution has its own mechanism to select the gateway. Typically, it is difficult to select the same gateway.       
 
         [0009]    In addition, Mobile IPv4 requires a method to configure clients. 
         [0010]    Hence, the handling of connection sessions in a network needs to be improved. 
       SUMMARY OF THE INVENTION 
       [0011]    Hence, it is an object of the present invention to solve the problem mentioned above and to provide mobility and session continuity even in case different mobility solutions are provided by a gateway. 
         [0012]    According to several embodiments of the present invention, this object is solved by a gateway comprising a supporting unit configured to support a plurality of connection session types; a providing unit configured to provide a connection session to a terminal; and an associating unit configured to associate a parameter with the connection session to the terminal. 
         [0013]    Alternatively, according to several embodiments of the invention the object is solved by a terminal comprising a supporting unit configured to support a plurality of connection session types; a providing unit configured to provide a connection session to a gateway; and a receiver configured to receive a parameter which is associated with the gateway. 
         [0014]    As a further alternative, according to several embodiments of the invention, the object is solved by a method for controlling a gateway in a network, wherein the gateway is able to support a plurality of connection session types, the method comprising: providing a connection session to a terminal; and associating a parameter with the connection session to the terminal. 
         [0015]    Moreover, according to several embodiments of the invention, the object is solved by a method for controlling a terminal, wherein the terminal is able to support a plurality of connection session types, the method comprising: providing a connection session to a gateway; and receiving a parameter which is associated with the gateway. 
         [0016]    According to exemplary embodiments of the invention, a system for providing mobility to a terminal through at least two different mobility protocols is provided, wherein:
       a mobility gateway and a terminal share a common mobility session,   said common mobility session can be updated through any of the said different mobility protocols, and   each mobility protocol provides information to the terminal related to all other mobility protocol during a registration.       
 
         [0020]    Thus, even in case a terminal changes the type of connection to a network control element (e.g., from WLAN to GPRS), the connection session as such can be clearly identified. Hence, the mobility and session continuity can be provided even in case different mobility solutions (different connection session types) are provided. 
         [0021]    That is, the invention provides a mobility solution in which multiple mobility technology can be combined and session continuity across these multiple mobility technologies is allowed. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0022]    The invention is described by referring to the enclosed drawings, in which: 
           [0023]      FIG. 1  shows a signalling flow where the terminal using the integrated mobility session first power-on using GPRS connection session type according to a first embodiment, 
           [0024]      FIG. 2A  shows a signalling flow where the terminal using the integrated mobility session first power-on using Mobile IP as a connection session type according to the first embodiment, 
           [0025]      FIG. 2B  a layer structure in terminal and gateway, 
           [0026]      FIG. 3  shows a signalling flow where the terminal using the integrated mobility session first power-on with GPRS as a connection session type according to a second embodiment, 
           [0027]      FIG. 4  shows a signalling flow where the terminal using the integrated mobility session first power-on with Mobile IP as a connection session type according to the second embodiment, 
           [0028]      FIG. 5  shows a signalling flow where the terminal using the integrated mobility session first power-on with GPRS connection session type according to a third embodiment, 
           [0029]      FIG. 6  shows a signalling flow where the terminal using the integrated mobility session first power-on with Mobile IP as a connection session type according to the third embodiment, and 
           [0030]      FIG. 7A  shows a basic configuration of a gateway according to the embodiments, and  FIG. 7B  shows a basic configuration of a terminal according to the embodiments. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0031]    In the following, preferred embodiments of the present invention is described by referring to the attached drawings. 
         [0032]    In general, the preferred embodiments propose an integrated mobility solution, where one gateway (also referred to as mobility gateway or integrated mobility gateway) supports a single mobility session through more than one mobility technology, and is able to return to the Mobile Node (MN) configuration parameters or session parameter to ensure that the MN will stay connected to this same gateway if mobility technology are used. In particular, the gateway allocates the same home address to the MN when the mobility technology changes during a session, so that the change of mobility technology is invisible to the correspondent node. 
         [0033]    Moreover, the terminal (i.e., the Mobile Node (MN)) is having a single mobility session, and has means to update this mobility session through different protocols (3GPP mechanism; Mobile IP; Mobike) depending on the access it is using. Furthermore, after accessing through one protocol, the MN will receive configuration/session parameters, and use them to configure the other protocols part of this mobility session. 
         [0034]    In the following, a more detailed example according to a first embodiment is described by referring to the signaling flow shown in  FIG. 1 . 
         [0035]    In this example, it is assumed that an Intelligent Service Node (ISN) (combining GGSN-MIPv4 Home Agent) is the gateway mentioned above, and that the MS first connect over GPRS. 
         [0036]    In the following, the signaling flow is described. This is started upon power-on in GPRS, wherein a co-location of GGSN and HA is provided 
         [0037]    In step A 1 , the UE (User Entity) or Mobile Station (MS) or Mobile Node (MN) sends a PDP (Packet Data Protocol) context request. Preferably the MS adds an indication that integrated MIPv4 mobility is supported. This is preferably added in the Protocol Configuration Option so that a SGSN transfer it transparently. In  FIG. 1 , the indication consists of a mobility session ID. A certain value e.g. 0000 indicates that no prior mobility session exists.+ 
         [0038]    Thereafter, an integrated mobility session is created in the ISN (step A 2 ). This integrated mobility session may be updated through GPRS or MIP as illustrated below. This integrated mobility session will not be terminated if the GPRS session is deactivated. But it will wait for a possible Mobile IP update. 
         [0039]    In step A 3 , the ISN returns a PDP context accept containing its MIPv4 HA (Home Agent) IP address (and/or optionally logical name HA NAI Home Address Network Access Identifier, as defined in RFC3846, for example), a temporary shared secret (valid for this session), a SPI (Security Parameter Index), and optionally a GGSN identity (preferably coded as an APN (Access Point Name)). Optionally, a unique mobility session identifier should be included. These are preferably added in the Protocol Configuration Option so that SGSN transfer it transparently. Note that the IP address returned to the MS in the PDP context activation response will be the MN address for the duration of the mobility session. So it will also be the Mobile IP home address. 
         [0040]    That is, as long as the MS stays in GPRS, it considers itself in its home network (from Mobile IP point of view) and does not use Mobile IP. ISN and the MS have a mobility session containing GPRS parameters, and temporary shared secret (valid for this session), SPI (Security Parameter Index). There is no active MIP session, but the MS has configured its Mobile IP stack with the parameters received from PDP context activation procedure (HA address; home address; shared secret; SPI). 
         [0041]    In step A 4 , it is now assumed that the MN detects a WLAN which has higher priority than the cellular network, e.g. its Home WLAN. 
         [0042]    Thus, in step A 5  it sends a MIP Registration Request (RRQ) to the HA address received in step A 3 . The authentication field is computed using the temporary shared secret and SPI received in step A 3 . The RRQ also includes the home address allocated in step A 3  by the GGSN. Preferably, the request includes also HA NAI (as proposed in RFC3846) and mobility session ID as a vendor extension. 
         [0043]    In step A 6 , the ISN receives the request and finds the proper session context using the session ID (Note that overlapping address support is assumed, so Home address is not enough to uniquely identify the MS). The ISN authenticates the MS and accept the request. That is, in step A 6 , the mobility session is identified through the mobility session ID, security procedures are performed to validate the request, and an update is performed in the ISN to route the session through this new access. 
         [0044]    In step A 7 , a corresponding response (R Resp) is sent to the MS. Optionally, the same mobility session identifier should be included (for protocol simplicity) in the accept message, as well as GGSN identity coded as APN. MIP session is established. E.g., an IP-in-IP tunnel is created and all traffic is now routed to the MS care-off address. 
         [0045]    ISN and the MS have a mobility session (referred by unique mobility session ID) containing GTP (GPRS Tunneling Protocol) parameters and MIP parameters. Both sessions are active. 
         [0046]    After this, SGSN may release the PDP context based on a timer (there is no data traffic is SGSN). So, in step A 8 , the PDP context is deactivated. In ISN, the parameters related to the GTP tunnel are erased. 
         [0047]    ISN and the MS have a mobility session (referred by unique mobility session ID) containing MIP parameters. The MS also contains the GGSN identity coded as APN. The GTP session is not active. 
         [0048]    In step A 9 , it is assumed that the MS moves back to cellular coverage. As it has an active mobility session it will not use its default APN, but use the one receive in step A 3  or A 7  (GGSN ID). Standard SGSN will route the request to the same ISN (as only one is associated with this APN). The MS adds the mobility session ID. This is preferably added in the Protocol Configuration Option so that SGSN transfer it transparently. 
         [0049]    In step A 10 , the ISN returns a PDP context accept containing its MIPv4 HA IP address (and optionally logical name HA NAI, as in RFC3846), temporary shared secret (possibly a new one valid for this session), SPI (Security Parameter Index), and GGSN identity (preferably coded as an APN). Optionally, the same mobility session identifier should be included (for protocol simplicity). These are preferably added in the Protocol Configuration Option so that SGSN transfer it transparently. 
         [0050]    In the following, another example is described by referring to the signaling flow shown in  FIG. 2A . In this example, an Intelligent Service Node ISN (combining GGSN-MIPv4 Home Agent) is assumed, and it is assumed that the MS first connects over Mobile IP (MIP). 
         [0051]    The signaling flow is as follow, which shows in particular a power-on in WLAN, and then a movement to GPRS, wherein GGSN &amp; HA co-location is ensured. 
         [0052]    In step B 1 , the MN connects through, e.g., a WLAN by sending a MIP Registration Request to a preconfigured HA address. The authentication field is computed using preconfigured shared secret and SPI. The RRQ also includes the MN NAI, in order to request a dynamic home address allocation. Preferably, the request includes also mobility session ID set to 0000 as a vendor extension. 
         [0053]    In step B 2 , the ISN receives the request, authenticates the MN, and detects it is a new session (since session ID is 000 in step B 1 ), allocates dynamically a home address, as well as a unique session identifier. The ISN returns GGSN identity coded as APN in the accept message. A MIP session is established. E.g., an IP-in-IP tunnel is created and all traffic is now routed to the MS care-off address. 
         [0054]    In step B 3 , the MN updates its GPRS configuration with the received APN for the duration of this mobility session. This is also illustrated in  FIG. 2B , in which the corresponding lay structure is illustrated. MIP, IP and WLAN is shown in bold in order to emphasize the settings. 
         [0055]    The layer structure is the same for the terminal and for the gateway. 
         [0056]    Moreover, the terminal may be a single device (e.g. mobile phone) or consists of many different device. 
         [0057]    For example, the common mobility layer may be on a laptop while the GPRS layer may be on a data card. 
         [0058]    As to the layer structure, it is noted that on top a common mobility layer is present. 
         [0059]    In the terminal, this common mobility layer provides:
       a virtual interface to the application.   A single home address common between MIP and GPRS   Possibility to change between GPRS and MIP without impact to the application   At the start of a session or during updates, the common mobility layer will configure one stack (e.g. GPRS) with the information received (GPRS APN; common session ID) through the other stack (e.g. MIP)       
 
         [0064]    In the following, the layer structure for the gateway is described, which is the same as shown in  FIG. 2B . 
         [0065]    The gateway is typically integrating many mobility technologies. 
         [0066]    The common mobility layer in the gateway:
       Controls the registration procedure.   Generates the information to be sent during the registration procedure to the MS (e.g. home address . . . )   Generates unique session ID   Maintains the session when the mobility protocol is changed   hides change between GPRS and MIP to any external correspondent nodes   At the start of a session a session and during updates, the common mobility layer will provide one stack (e.g. GPRS) with the information to be sent to the terminal (MIP HA address; security parameters; HA names; common session ID) related the other stack (e.g. MIP)       
 
         [0073]    In step B 4 , it is now assumed that the MN loses WLAN connectivity, so that it now moves to GPRS. 
         [0074]    Thus, in step B 5 , the MN sends a create PDP request including the mobility session ID received in step B 2  and using APN received in step B 2 . The SGSN selects the GGSN normally (e.g. with a DNS (Domain Name Server)). The network is configured so that this APN uniquely points to the ISN selected in step B 1 . mobility session ID is preferably added in the Protocol Configuration Option so that SGSN transfer it transparently. 
         [0075]    In step B 6 , the ISN returns a PDP context accept containing its MIPv4 HA IP address (and optionally logical name HA NAI, as in RFC3846), temporary shared secret, SPI (Security Parameter Index). Optionally, the same mobility session identifier should be included (for protocol simplicity). These are preferably added in the Protocol Configuration Option so that SGSN transfer it transparently. 
         [0076]    Step B 7  and B 8  on the figure shows what happens when the MS moves back to a MIP connection. 
         [0077]    In particular, in step B 7 , the MN sends a MIP RRQ to the ISN, including the mobility session ID (which may be in this case 1111, for example). In step B 8 , the ISN sends a R Resp to the MN, including the vendor extension defining the ISN (namely APN=“GGSN/HA7”), Address of the Home Agent (HoA) and the mobility session ID. 
         [0078]    In the following, the Mobile Node implementation is described. A preferred way to implement the MS is to have a combined mobility layer between the application and the GPRS stack/MIP stack. The application will use a virtual interface to connect with this combined mobility layer and receive through this interface its Home address. The combined mobility layer will store in a context the information related to the mobility session, track the active interface (MIP or GPRS), and configure the MIP and GPRS protocol with the appropriate parameters for the active mobility session. When the mobility session is terminated, the combined mobility layer may erase the parameters related to that mobility session. GPRS and MIP stack will then use preconfigured parameters the next time a connection is established. 
         [0079]    According to the first embodiment, a mobility session ID is used as the parameter for identifying a connection session (such as a mobility session). Namely, the assumption is that one MN can have many simultaneous sessions. Mobility Session ID is a robust way to uniquely identify the right session. The IP address cannot be used to uniquely identify the session, as private address may overlap. 
         [0080]    The MN identity could be used to uniquely identify the session, but it would limit the number of session to one by MN. It is not practical as different mobility protocols typically used different type of identity. That would not support concept like UMTS router (having many computers connected behind one UMTS modem) 
         [0081]    As mentioned above, this mobility session ID (also abbreviated as session ID only) can be used that integrated mobility is supported and can be used. This can be indicated in step A 1  by a session ID containing only 000000. 
         [0082]    Security consideration: The mechanism proposed is reasonably secure as the temporary shared secret is returned over GPRS which is encrypted over the radio. For higher security, this shared secret could be returned in an encrypted form. There are many other possibility to enhance the security but it is not the main topic here. 
         [0083]    Backward compatibility: Old GGSN or HA will just ignore the new field. The MS should be able to interwork with them and have separate GPRS and MIP session. 
         [0084]    If the first connection is over MIP, the MS needs to have a preconfigured shared secret, and MIP HA. However an alternative is that the MS will always first connect to GPRS. Another alternative is that the MS and network store the parameters from the previous session. 
         [0085]    In the following, a second embodiment is described by referring to  FIGS. 3 and 4 . 
         [0086]    According to the first embodiment described above, the GPRS signaling includes MIP parameters, and the MIP signaling includes GPRS parameters. That is, for example the mobility session ID is included in the PDP context accept message (step A 3 ). 
         [0087]    However, according to the second embodiment, the GPRS signalling triggers a MIP message (Agent Advertisements) carrying MIP parameters (including the mobility session ID), instead of sending them inside the GPRS signaling. 
         [0088]    In  FIG. 3 , a corresponding modification of the signaling flow of  FIG. 1  is shown. Here, the steps C 1  to C 10  are identical to the steps A 1  to A 10 , except for steps C 3  and C 10  and the addition of steps C 3   bis  and C 10   bis.    
         [0089]    In steps C 3  and C 10 , only the PDP context accept message is sent, without other parameters. Instead, in steps C 3   bis  and C 10   bis  an Agent Advertisement message including those parameters is sent. 
         [0090]    In  FIG. 4 , a corresponding modification of the signaling flow of  FIG. 2  is shown. Here, the steps D 1  to D 8  are identical to the steps B 1  to B 8 , except for step D 6  and the addition of step D 6   bis.    
         [0091]    Similar as in  FIG. 3 , in step D 6 , only the PDP context accept message is sent, without other parameters. Instead, in step D 6   bis  an Agent Advertisement message including those parameters is sent. 
         [0092]    In the following, a third embodiment is described, in which the parameter for identifying 
         [0093]    According to this embodiment, HA NAI is used for identifying the ISN. This is shown in  FIGS. 5 and 6 . 
         [0094]    The use of HA NAI is in particular advantageous if there is a cluster of HA behind one IP address. Namely, the HA NAI will uniquely identify one of the HA. In Flexi ISN case it could uniquely identify the right service card. It should be noted that the protocol could be designed so that HA NAI=GGSN APN, providing a unique identity for the ISN. 
         [0095]    In a preferred implementation according to the present embodiment, a single logical name is associated to the ISN. This name may be used either as the HA NAI (RFC3846) or as the GPRS APN (Access Point Name). The benefit is that standard MIP signaling can be used (No new vendor extension to send back the APN, but just HA NAI is sent). The client will then use the returned logical name as an APN for the GPRS signaling. 
         [0096]    This is illustrated in  FIGS. 5 and 6 , in which steps E 1  to E 10  and F 1  to F 8  are identical to steps A 1  to A 10  and B 1  to B 8  of  FIGS. 1 and 2 , respectively, except for steps E 7 , E 9 , F 2 , F 5  and F 8 . 
         [0097]    In  FIG. 5 , in step E 7 , in the R Resp message, the HA NAI is sent instead of the GGSN identity. This is used for the PDP context request in step E 9 . 
         [0098]    In  FIG. 6 , in steps F 2 , F 5  and F 8 , the R Resp contains the HA NAI instead of the vendor extension as in steps B 2 , B 5  and B 8  of  FIG. 2 . 
         [0099]    Thus, by means of the embodiments described above, a connection session can always be reliably be identified. The implementation does not cause no overhead over GPRS, it provides a simplified configuration, and traffic will go through only one gateway instead of two. Moreover, 3GPP operators have now a way to retain control of the subscriber. 
         [0100]      FIG. 7A  illustrates a basic configuration of a gateway according to the present embodiments. In particular, the gateway  1  may comprise a supporting unit configured to support a plurality of connection session types, a providing unit  12  configured to provide a connection session to a terminal, and an associating unit  13  configured to associate a parameter with the connection session to the terminal. 
         [0101]      FIG. 7B  illustrates a basic configuration of a terminal according to the present embodiments. The terminal  2  may comprise: a supporting unit  21  configured to support a plurality of connection session types, a providing unit  22  configured to provide a connection session to a gateway, and a receiver  23  configured to receive a parameter which is associated with the gateway. 
         [0102]    The invention is not limited to the embodiment described above, and various modifications are possible. 
         [0103]    For example, the invention is not limited to the mobility protocols described above, but is also applicable to other mobility protocols. Following the principles described here, a combined mobility session may support connectivity through more than 2 underlying protocols. 
         [0104]    A particularly relevant example is combining the 3GPP LTE (Long Term Evolution) mobility, GPRS and Mobike. In that case, when the IPsec connection is established through Mobike, extension to MObike will provide the MN with the identifier of the ISN (alternatively there might be 2 identifiers one for LTE and one for GPRS) and a unique mobility session identifier. When the MS moves under the 3GPP LTE network it will sends the identifier of the ISN to be connected to the same gateway, and this gateway will uniquely identify the session through the mobility session identifier. As the same IP address will be allocated to the MS, external correspond node will not detect any changes. 
         [0105]    Similarly, the invention is also applicable to MIPv6. One difference is that security parameters are slightly different in MIPv6. Another difference in MIPv6, is that the home IPv6 address is unique, and session ID parameter could be avoided in some cases. 
         [0106]    Moreover, the invention is not limited to mobile connection sessions only. That is, also fixed network access points could be included. For example, a laptop computer may have access via WLAN, but can also be connected via a network cable.