Abstract:
A method, a system, and a local network switching device for providing access for a mobile communication terminal and the mobile communication terminal at a moved location to an Internet network via wireless local networks. The mobile communication terminal is moved from a first network to a second network. The WLAN handover, necessary therefore, takes place efficiently and in a robust manner, by providing access for the mobile communication terminal in the first network, by transmitting a device-specific address to a plurality of bordering networks, and by configuring further accesses on the plurality of bordering networks. After moving the mobile communication terminal, access to an Internet network can be continued immediately via the second network, via the local network switching unit of the second network, and via the local network switching unit of the first network.

Description:
BACKGROUND OF THE INVENTION 
     (1) Field of the Invention 
     The present invention relates to a method, a system and a local network switching unit for providing access for a mobile communication terminal and the moved mobile communication terminal to an Internet network via wireless local networks. The invention relates in particular to a method and system for the efficient handover of the access to an Internet network to a mobile communication terminal which is moved from a first wireless local network to a further wireless local network. 
     (2) Description of the Related Art 
     Wireless local networks, so-called Wireless Local Area Networks (WLAN), serve as communication systems for communicating with other communication units for users with mobile communication terminals. Wireless local networks are used primarily as access networks for access to a fixed network, and in particular for access to the Internet. In a WLAN, data are transmitted in each case via an air interface. Data are thereby transmitted from one point to another by means of electromagnetic waves, in particular radio or infrared waves. A typical WLAN comprises at least one point of access, or so-called Access Point (AP), and at least one wireless communication terminal, for example a laptop or palmtop computer, for instance a so-called Personal Data Assistant (PDA), or a mobile telephone. An access point comprises at least one transmitter/receiver and an antenna for data exchange with the wireless communication terminals via an air interface. A device configuration embodying such an access point will be designated in this text as an access point unit. An access point unit is normally assigned a local network switching unit, which local network switching unit is typically connected to the access point unit via a physical network. A local network switching unit has the task, among others, of enabling network connections between the communication terminals existing in a wireless local network and further communication terminals connected to the local network switching unit. However, a local network switching unit can also enable e.g. network connections between the communication terminals existing in a wireless local network. Local network switching unit and access point unit can be combined into a single device. Such a device will be designated in this text as a switching device. An access point unit is normally set up at a fixed location, data being able to be exchanged only with communication terminals located within the range of this access point unit. The range of an access point unit depends upon various factors such as the access point unit itself, the environment and the mobile communication terminal. To enable access via wireless local networks in a larger area, a corresponding number of access point units are distributed over this larger area in such a way that a mobile communication terminal has access to at least one of the access point units from as many points as possible of this larger area. For a mobile communication terminal moving out of the range of a first access point unit into the range of a second access point unit, the access of the mobile communication terminal must be switched over from the first access point unit to the second access point unit. This switching step is also designated as a “WLAN handover,” whereby, in other words, the changeover takes place from the first wireless local network, assigned to the first access point unit, to the second wireless local network, assigned to the second access point unit. A WLAN handover must be carried out as efficiently as possible, it being meant by efficient that the access of the mobile communication terminal may not be interrupted, or only as briefly as possible. An efficient WLAN handover is of especially great importance for applications such as IP (Internet Protocol) telephony. For efficient WLAN handovers there exist at the present time only solutions for wireless local networks within locally limited zones, in particular for wireless local networks of a locally limited zone of the same network provider, especially for wireless local networks inside the same building or building complex. An efficient WLAN handover between, for example, wireless local networks spread out over larger geographic regions or between different network providers, is, on the other hand, an unsolved problem. Apart efficiency, a WLAN handover should take place in an as robust manner as possible. Robustness of a WLAN handover is partly connected to efficiency of a WLAN handover. When a mobile terminal is just on the border of the ranges of two different access points, it may become difficult to decide which of these access points shall be used. This may lead to a situation where the mobile terminal connects to the first access point, then detects a better signal quality of the second access point and therefore starts to register to the second access point. While establishing a connection to the second access point, the signal quality for the first access point may have increased again and the mobile terminal may therefore start again to register with the first access point. If efficiency of a WLAN handover is low, also robustness for connecting to a WLAN in such a situation as is low. Robustness may be even more degraded due to the fact that some central server behind the access points has to manage connections from the mobile terminal to the Internet. For managing such connections, rerouting of data streams may be necessary. However, when a mobile terminal switches its registration between different access points back and forth, the design of a robust central server for managing connections from the mobile terminal to the Internet becomes a difficult task. A further disadvantage in the state of the art is handling of a WLAN handover between different network providers. In the state of the art, when a mobile terminal moves from an access point of a first network provider to the access point of a second network provider, the mobile terminal has to be fully registered to the network provider again. Even if different network providers would like to share access points in between each other, such that customers of a first network provider may benefit from network resources of a second network provider, such a sharing of access points is not possible in the state of the art. 
     The document RFC 2002, October 1996, (the document is also known as “Mobile IP”) of the Internet Engineering Task Force (IETF) describes a protocol for access to the Internet for mobile nodes. A mobile node thereby has two IP addresses. The first IP address is the so called home address, which is assigned to the mobile node in a fixed way. The second IP address is the so-called care-of address, which is newly assigned again in each case during a change from a first physical network to a further physical network. The home address is made known to the Internet by a so-called home agent. Data which are intended for the mobile node are first sent to the home agent, who forwards these data to the current care-of address of the mobile node. Mobile IP makes it possible for a mobile node to be able to switch between physical networks of the same kind (such as e.g. from a first ether network to a further ether network) as well as to be able to switch between physical networks of a different kind (such as e.g. from an ether network to a WLAN). With mobile IP a mobile node can also switch from a first wireless local network to a further wireless local network, a change between different network providers also being possible. With mobile IP it is not possible, however, to achieve a sufficiently efficient WLAN handover. With mobile IP it is also not possible to provide a robust WLAN handover. And finally, with mobile IP it is also not possible that network providers may share network resources in between each other. 
     In “Application-Layer Mobility Using SIP” (ACM SIGMOBILE Mobile Computing and Communications Review, Volume 4, Number 3, 2000, 47-57), Schulzrinne et al. have proposed a SIP (Session Initiation Protocol) based handover. A mobile node receives a beacon when it enters the radio range of a new WLAN base station. The mobile node initiates a discovery protocol for receiving a new IP address and invites the calling host to this new address. Schulzrinne et al. consider SIP-based mobility to be less suitable for TCP-based applications. With SIP based handover, however, it is not possible to provide for a sufficiently efficient WLAN handover. It is as well not possible to provide for a robust WLAN handover. And finally, with SIP based handover it is also not possible that network providers may share network resources in between each other. 
     The patent application US 2003/0185172 discloses a method for supporting mobility of a mobile node between access points of a WLAN (wireless local access network). The method is initiated by moving the mobile node from a first WLAN, where the mobile node currently is connected, to a second WLAN. After moving the mobile node, a message containing the mobile nodes medium access control (MAC) address is broadcasted by a second access server of the second WLAN. A first access server of the first WLAN receives the broadcasted message and sends a message containing the Internet protocol address of the mobile node to the second access server. Data routing to and from the mobile node is then established via the second access server via the first access server to the Internet. A disadvantage of the method according to US 2003/0185172 is that a sufficiently efficient WLAN handover is difficult to achieve. It is also a disadvantage that robustness of a WLAN handover cannot be achieved. When the mobile node moves from a first network provider to a second network provider, it is a disadvantage that the mobile node has to be newly registered to the second network provider. 
     BRIEF SUMMARY OF THE INVENTION 
     It is the object of the present invention to propose a new method and system for providing the access of a mobile communication terminal and the moved mobile communication terminal to an Internet network via wireless local networks, the access of the mobile communication terminal being provided by a first wireless local network and further wireless local networks, which method and system do not have the drawbacks of the prior art. 
     These objects are achieved according to the present invention through the elements of the independent claims. Further preferred embodiments follow moreover from the dependent claims and from the specification. 
     The above-mentioned objects are achieved through the present invention in that the mobile communication terminal is registered in a first Internet switching unit via a first access point unit of a first wireless local network and via a first local network switching unit (SW 1 ) connected to the first access point unit, in that a first Internet address is transmitted from the first Internet switching unit to the mobile communication terminal, in that a first access for the mobile communication terminal to the Internet network is provided, using the first Internet address, whereas the first access is via the first access point unit, via the first local network switching unit, and via the first Internet switching unit, in that in the first local network switching unit a device-specific address of the mobile communication terminal is registered, in that the registered device-specific address and a network identification for the first wireless local network is transmitted from the first local network switching unit to a plurality of bordering further local network switching units, and in that the plurality of bordering further local network switching units are configured for providing a plurality of further accesses for the mobile communication terminal at a moved location to the Internet network using the first Internet address, whereas the plurality of further accesses is via a plurality of further access point units and corresponding further bordering local network switching units, via the first local network switching unit and via the first Internet switching unit. Such wireless local networks and such a mobile communication terminal have the advantage that access to an Internet network for a mobile communication terminal can be achieved with an efficient WLAN handover also for spread-out wireless networks. Since a device-specific address for the mobile communication terminal is registered in the first local network switching unit, and this registered address is transmitted together with a network identification for the first wireless local network to bordering further local network switching units, sufficient information exists—with the network identification and the device-specific address—at the point in time of movement of the mobile communication terminal to a new location of a bordering second access point unit, at the second local network switching unit, assigned to this second access point unit, such that data may be instantly exchanged between the mobile communication terminal, the second local network switching unit, the first local network switching unit and an Internet network. Through this method, a robust and efficient WLAN handover is achieved. Moreover, deployment of local network switching units can be easily performed. 
     In an embodiment variant, routing in the first local network switching unit of data packets from the Internet network to the first access or to the further accesses is adapted according to data packets of the mobile terminal or the moved mobile terminal received from the first access to the Internet network or from the further accesses to the Internet network. Such an embodiment variant has the advantage that routing of data packets towards the mobile terminal is efficiently adaptable to the current location of the mobile terminal. 
     In an embodiment variant, during registration of the network identification and of the device-specific address of the mobile communication terminal, network connections are also established between the current wireless local network of the mobile communication terminal and bordering further wireless local networks. This embodiment variant has the advantage, among other things, that after movement of the mobile communication terminal an initialized network connection is already established between the second local network switching unit and the first local network switching unit, whereby an even more efficient WLAN handover can be achieved. 
     In a further embodiment variant, after the WLAN handover according to the invention, the mobile communication terminal will be assigned a second Internet address from the second Internet switching unit assigned to the second local network switching unit; a device-specific address will be registered and will be transmitted together with a network identification for the second local network switching unit to bordering further local network switching units, and access for the mobile communication terminal to the Internet will be provided via the second access point unit using the second Internet address. This embodiment variant has the advantage, among other things, that the mobile communication terminal uses an Internet address assigned to the second wireless local network, and therefore, for instance, with movement of the mobile communication terminal into a third wireless local network, only one connection to the second local network has to be used. 
     In a further embodiment variant, one or more, or all, access point units and the local switching unit assigned to an access point unit are combined in each case into a switching device, and used as the device-specific address is the Media Access Control (MAC) address of the wireless local network. This embodiment variant has the advantage, among other things, that commercially available switching devices can be used, and, with the MAC address, a standardized device-specific address. 
     In a further embodiment variant, the bordering local network switching units are connected to each other via layer 2 tunnel connections (Layer 2 Tunnel Protocol or L2TP), and the mobile communication terminal is registered in a first virtual local network via the first access point unit. After the mobile communication terminal has been moved to a new location, and after transmission of the second Internet address, the mobile communication terminal is registered in a second virtual local network, via the second access point unit, and deregistered in the first virtual local network. This embodiment variant has the advantage, among other things, that with the use of virtual networks a widespread technology can be used. 
     In a further embodiment variant, access of the mobile communication terminal to an Internet network from the access point unit, from the local network switching unit and/or from the Internet switching unit is checked via security keys, via policies and/or via one or more authentication methods. This embodiment variant has the advantage, among other things, that a mobile communication terminal can be identified and the access to an Internet network can be billed, for instance. 
     In a further embodiment variant, the access point unit, the local network switching unit and/or the Internet switching unit is checked by the mobile communication terminal via security keys, via policies and/or via one or more authentication methods. This embodiment variant has the advantage, among other things, that the mobile communication terminal can identify network elements and can establish access to an Internet network e.g. only with respect to certain providers. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       An embodiment of the present invention will be described in the following with reference to an example. The example of the embodiment is illustrated by  FIGS. 1 to 4 : 
         FIG. 1  shows a block diagram representing schematically wireless local networks and a mobile communication terminal, the mobile communication terminal moving in step W from the wireless local network WLAN 1  to the wireless local network WLAN 2 . 
         FIG. 2  shows a block diagram illustrating schematically a possible sequence of steps for access of a mobile communication terminal via wireless local networks. 
         FIG. 3  shows a block diagram illustrating schematically a first access T 1  and a plurality of further accesses T 12 , T 13 , T 14  for the mobile communication terminal using a first Internet address. 
         FIG. 4  shows a block diagram illustrating schematically a second access T 2  and a plurality of further accesses T 21 , T 23 , T 24  for the mobile communication terminal using a second Internet address. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In  FIG. 1 , the reference numeral  61  refers to a wireless communication terminal, for example a laptop or palmtop computer, for instance a so-called Personal Digital Assistant (PDA), or a mobile telephone. The wireless communication terminal  61  comprises a communication module for data communication via a wireless local network, a so-called WLAN (Wireless Local Area Network). The wireless local network is preferably based on radio waves, for example according to the standard IEEE 802.11 (Institute of Electrical and Electronics Engineers) or according to a standard for a piconet, e.g. according to the standard known by the name Bluetooth. It can also be based on infrared, however. Subsequently, the terms mobile communication terminal  61  and moved mobile communication terminal  62 ,  63 ,  64  are used, whereas the mobile communication terminal  61  is initially located at a first location and whereas, through a movement W from the first to the second location, the moved mobile communication terminal  62 ,  63 ,  64  is located at a second location. 
     As shown in  FIG. 1 , because of the limited range of wireless local networks, a plurality of access point units, so-called Access Points (APs), are set up in a distributed way, to enable access to an Internet network via wireless local networks over larger geographic areas. Illustrated in  FIG. 1 , by way of example, are four access point units AP 1 , AP 2 , AP 3  and AP 4 ; the present invention relates, however, to configurations with any desired number of access point units and any desired number of (subsequently shown) corresponding units, devices and similar components. Each access point unit is assigned to a corresponding local switching unit. In the example of  FIG. 1  these are the local switching units SW 1 , SW 2 , SW 3  and SW 4 . 
     Access point unit and local switching unit can be separate units which are connectable to each other via a data connection, or access point unit and local switching unit can be combined into a single device. In the case of a single device, access point unit and local switching unit form the so-called switching device. In  FIG. 1  these are the switching devices  1 ,  2 ,  3  and  4 . It is obvious that a switching device can be replaced by an access point unit and a local switching unit. A switching device is assigned a corresponding wireless local network. In  FIG. 1  these are the wireless local networks WLAN 1 , WLAN 2 , WLAN 3  and WLAN 4 . 
     Local switching units can be connected to one another via a physical network cable, such as e.g. the Ethernet. Local switching units can also be connected to one another via Internet switching units and an Internet network, however. In  FIG. 1 , the reference numerals  14  and  23 , respectively, refer to direct connections via physical networks that connect the local switching units SW 1  and SW 4  or SW 2  and SW 3 , respectively. The reference symbols ISP 1  and ISP 2 , respectively, in  FIG. 1  refer to Internet switching units that connect the local switching units SW 1  and SW 2 , respectively, via an Internet network  5 . 
     In the case of connection of local switching units via an Internet network, it can be advantageous to achieve this connection wholly or partially as a so-called layer 2 tunnel connection (Layer 2 Tunnel Protocol or L2TP). In  FIG. 1 , the reference numeral  12  refers to a layer 2 tunnel connection between the Internet switching units ISP 1  and ISP 2 . A layer 2 tunnel connection can also be achieved, however, between local switching units, such as e.g. between the local switching unit SW 1  and the local switching unit SW 2 . 
     The reference numeral  61  in  FIG. 1  refers to the mobile communication terminal which is connected wirelessly to the access point unit AP 1 . The step W refers to the movement of the mobile communication terminal from a first wireless local network WLAN 1  into a further wireless local network WLAN 2 . The reference numeral  62 ,  63 ,  64  refers to the moved communication terminal (i.e. after the mobile communication terminal has been moved according to step W), which is wirelessly connected to one of the access point units AP 2 , AP 3 , AP 4 . 
     In  FIG. 2 , the reference numeral  61  refers to the mobile communication terminal. The reference symbol AP 1 /SW 1  refers to a first switching unit, comprising a first access point unit AP 1  and a first local network switching unit SW 1 . The reference symbol AP 2 /SW 2  refers to a second switching unit, comprising a second access point unit AP 2  and a second local network switching unit SW 2 . The reference symbol ISP 1  refers to a first Internet switching unit, and the reference symbol ISP 2  refers to a second Internet switching unit. 
     In step S 1 , a one-sided or a mutual recognition is carried out between the mobile communication terminal  61  and the switching device AP 1 /SW 1 . In step S 2 , the mobile communication terminal  61  transmits to the switching device AP 1 /SW 1  a request for granting access to an Internet network. 
     In a step S 2 ′, the switching device AP 1 /SW 1  forwards this request to the Internet switching unit ISP 1 . In a step S 3 , the Internet switching unit ISP 1  transmits a first Internet address for the mobile communication terminal to the switching device AP 1 /SW 1 . The switching device AP 1 /SW 1  transmits this first Internet address to the mobile communication terminal  61  a step S 3 ′. As depicted in  FIG. 3 , in a step S 4 , the mobile communication terminal  61 , the switching device AP 1 /SW 1  and the Internet switching unit ISP 1  agree on suitable settings and provide an access T 1  for the mobile communication terminal to an Internet network  5 . In step S 5 , the switching device AP 1 /SW 1  registers a device-specific address for the mobile communication terminal  61 . Together with a network identification for the wireless local network WLAN 1  assigned to the switching device AP 1 /SW 1 , the device-specific address is transmitted to bordering further switching devices AP 2 /SW 2  . . . APn 1 /SWn 1 , and is registered in these further switching devices AP 2 /SW 2  . . . APn 1 /SWn 1 , in step S 6 . In step S 7 , the switching device AP 2 /SW 2  transmits a request for establishing a two-way connection to the switching device AP 1 /SW 1 . The switching devices AP 1 /SW 1  and AP 2 /SW 2  then establish a connection X 1  for mutual data exchange. 
     In step W the mobile communication terminal  61  is moved from the switching device AP 1 /SW 1  to the switching device AP 2 /SW 2 . The reference numeral  62  designates the moved mobile communication terminal. 
     In step S 11 , a two-way recognition is carried out between the mobile communication terminal  62  and the switching device AP 2 /SW 2 . In step S 111 , the switching device AP 2 /SW 2  sends a command to the switching device AP 1 /SW 1  to use the connection X 1  in order to form the connection T 12  shown in  FIG. 3 , whereby access for the mobile communication terminal  62  (shown in  FIG. 4 ) to an Internet network, via the switching device AP 2 /SW 2 , via the switching device AP 1 /SW 1 , via the Internet switching unit ISP 1  is provided.  FIG. 3  further shows that connections T 11  and T 13  are also provided via switching devices AP 4 /SW 4  and AP 3 /SW 3  respectively. As depicted in  FIG. 4 , in step S 12 , the mobile communication terminal  62  transmits a request to the switching device AP 2 /SW 2  for grant of access to an Internet network  5 . In a step S 12 ′, the switching device AP 2 /SW 2  forwards this registration request to the Internet switching unit ISP 2 . In a step S 13 , the Internet switching unit ISP 2  transmits to the switching device AP 2 /SW 2  a second Internet address for the mobile communication terminal. The switching device transmits this second Internet address to the mobile communication terminal in a step S 13 ′. In a step S 14 , the mobile communication terminal  62 , the switching device AP 2 /SW 2  and the Internet switching unit ISP 2  agree on suitable settings and provide a connection T 2  for access for the mobile communication terminal to an Internet network. The connection T 2  can then be established. In step S 15  the switching device AP 2 /SW 2  registers the device-specific address for the communication terminal  62 . In step S 16 , together with a network identification for the wireless local network WLAN 2 , assigned to the switching device AP 2 /SW 2 , the device-specific address is transmitted to further switching devices AP 1 /SW 1  . . . APn 2 /SWn 2  and is registered in these further switching devices AP 1 /SW 1  . . . APn 2 /SWn 2 . In step S 17 , the switching device AP 2 /SW 2  transmits a request for providing a two-way connection to the switching device AP 1 /SW 1 . The switching devices AP 1 /SW 1  and AP 2 /SW 2  then establish a connection X 2  for mutual data exchange and form the connection T 21  as shown in  FIG. 4 .  FIG. 4  further shows that connections T 24  and T 23  are also provided via switching devices AP 4 /SW 4  and AP 3 /SW 3  respectively. 
     With this method the mobile communication terminal can be moved from a first wireless local network to a subsequent wireless local network, the WLAN handover taking place efficiently and in a robust manner. In particular, the WLAN handover also take place efficiently between different network segments of different network providers. Moreover, network providers may easily provide wireless access to each others customers, whereas billing of such access may be provided by measurement of data traffic passing from one network provider to customers of another network provider.