Procedure for Handling Location Information in a Core Network with Pooled Servers
Field of invention
The invention relates to a procedure for handling location information of a mobile station in a mobile communication network.
Description of prior art
The evolution of communication networks is undergoing a change from second to third generation networks. Among the characteristics of a third generation network is the possibility of offering different types of connections e.g. based on circuit switched and on packet switched transmission at the same time to a user of a mobile station.
Due to the limited radio coverage area of a single antenna and because of the demand to reuse the limited resource of bandwidth on the air interface, coverage areas of communication networks are divided into cells. In order to be able to page a mobile station in a limited number of such cells, groups of cells are defined, that shall be referred to as subareas. Location information comprising identifications of such subareas related to identifications of mobile stations is stored in network nodes which can be contacted for routing.
As different connection types have different demands on transmission properties and signalling, the demands on the size of the subareas can also differ. For this reason different kinds of subareas may be related to different types of connections. Subareas of a first kind can be related to a first type of connection, e.g. Location Areas for a Global System for Mobile Communication (GSM) network are related to circuit switched connections and subareas of a second kind can be related to a second type of connection, e.g. Routing Areas
for a General Packet Radio Service (GPRS) network are related to packet switched connections.
In a telecommunication network different kinds of network nodes can store identifications of the different kinds of subareas e.g. Mobile Services Switching Centres/ Visitor Location Registers (MSC/VLRs) in a GSM network store identifications of Location Areas referred to as Location Area Identities according to GSM specifications and Serving GPRS Support Nodes (SGSNs) store identifications of Routing Areas referred to as Routing Area Identities according to GPRS specifications.
Location information has to be updated frequently. For example, if a mobile station is entering another subarea in idle or active mode or if it has entered another subarea in detached mode and first switches on to idle mode, location information has to be updated in the network node that holds location information related to said mobile station. If the network node that last held the location information related to a detached mobile station has cleared said location information, a new network node that can store location information related to the mobile station has to be determined. In both cases location information comprising an identification of the subarea the mobile station is in has to be transmitted to the network node that is related to the mobile station. The procedure for handling location information of a roaming mobile station in idle mode is a Location Area Update in a GSM network respectively a Routing Area Update in a GPRS network. The procedure for handling location information of a mobile station that has been roaming in detached mode and switches to idle mode is an IMSI Attach in a GSM network respectively a GPRS Attach in a GPRS network.
In a telecommunication network with different kinds of subareas, the procedures for transmitting location information for the different kinds of subareas can be combined in order to save radio resources, especially if subareas of a first kind are enclosed by subareas of another kind. This is applied in a Combined Location Area/ Routing Area Update Procedure respectively in a Combined GPRS/ IMSI Attach Procedure as described in 3G
TS 23.060 V3.6.0 of the 3rd Generation Partnership Project. When a mobile station is entering a Routing Area it sends a Routing Area Update Request respectively an Attach Request to the SGSN related to the Routing Area it is in. The request comprises the new Routing Area Identity, the new Location Area Identity and the Packet Temporary Mobile Subscription Identity (P-TMSI), that is used to protect the privacy of the subscriber over the radio interface, if the P-TMSI is available to the mobile station. If the P-TMSI is not available to the mobile station, the International Mobile Subscriber Identity (IMSI) is used instead of the P-TMSI to identify the mobile station.
If the P-TMSI has been sent to the SGSN, the SGSN determines the IMSI related to the P- TMSI. The SGSN stores the Routing Area Identity and sends a Location Update Request to the MSC/VLR related to the Location Area, the request comprising the Location Area Identity and the International Mobile Subscriber Identity (IMSI) related to the mobile station. The MSC/VLR stores the Location Area Identity related to the International Mobile Subscriber Identity.
In a hierarchical network a set of Routing Areas is served by one related SGSN and a set of Location Areas is served by one related MSC/VLR. Therefor, the SGSN can determine on the basis of the Location Area Identity it has received the MSC/VLR to which it sends the Location Update Request.
If the subareas are small as is the case in urban areas, in a hierarchical network the signalling traffic transferring location information can be a considerable percentage of the overall traffic. If the operator is not allowed to charge signalling, this is also economically disadvantageous.
A fixed relation between subareas and related network nodes is broken up in the Pool Concept that is described in 3G TS 23.236 V2.1.0 of the 3rd Generation Partnership Project. In order to reduce the number of changes of the network node holding location information of a mobile station, in the Pool Concept the area in which said mobile station can roam
without changing the network node holding its location information is enlarged. To limit the number of mobile stations that are handled by one network node, subareas are jointly handled by network nodes i.e. different network nodes can store location information related to different mobile stations that are in a certain subarea. Therefore in the Pool concept there is no unique relation from one subarea to its related network nodes and the network node related to a mobile station cannot be determined on the basis of the identification of the subarea the mobile station is in.
This unique relation is used in the combined method to handle location information in a hierarchical network according to state of the art: The SGSN sends the Location Update Request to the MSC/ VLR which is related to the Location Area the mobile station is in. As the MSC/ VLR related to the mobile station cannot be determined based on the Location Area Identity in the Pool Concept, according to the state of the art there is no combined method available to handle location information for networks according to the Pool Concept. Therefore different messages comprising location information related to the different kinds of subareas have to be sent which increases the signalling traffic over the air interface. This is especially disadvantageous due to the limited bandwidth available and due to the high cost related to the licences for the usage of the limited spectrum.
If a fixed relation between a set of SGSNs and one MSC/ VLR would exist, the MSC/ VLR which is related to the mobile station could be determined based on this fixed relation. However this fixed relation between SGSNs and MSC/ VLRs is disadvantageous if the operator wants to change the configuration of the network, e.g. increase the number of MSC/ VLRs independent of the number of SGSNs and the configuration of the SGSNs. Furthermore in a network with a fixed relation between SGSNs and MSC/VLRs in case of a downtime or failure of a SGSN, the related MSC/VLR cannot be reached either. I.e. the a network with a fixed relation of between SGSNs and MSC/VLRs is less reliable than a network according to the Pool Concept.
Object of the invention
Therefore it is an object of the invention to avoid the above disadvantages and provide a method for a combined handling of location information according to subareas of different kinds in which different nodes can handle location information for a mobile station in the same subarea.
Summary of the invention
This object is solved by the method of claim 1 the network nodes of claim 14 and 15, the computer program of claim 16 and the computer program storage medium of claim 17. Advantageous embodiments are described in dependent claims.
According to the present invention a mobile station MS is roaming in the coverage area of a mobile communication network in which two different kinds of subareas exist, which are referred to as subareas of the first kind and subareas of the second kind. Network nodes store location information i.e. an identification of a subarea related to an identification of a mobile station MS. The mobile station MS is in a subarea of the first kind which is referred to as the first subarea RA1 and in a subarea of a second kind which is referred to as the second subarea LAI. Different network nodes are adapted to store location information comprising an identification of the first and of the second subarea LAI. Among the network nodes that can store location information a controlling network node CNl that is adapted to store an identification of the first subarea RA1 is related to the mobile station MS. For example the controlling network node CNl can either store an identification of a subarea of the first kind related to the mobile station MS or the controlling network node CNl related to the mobile station MS is determined by a radio network node that is related to the first subarea RA1. Either the controlling network node CNl is uniquely adapted to store location information according to the first subarea RA1 or the controlling network node CNl is a member of a set of network nodes that are adapted to store location information according to the first subarea RA1.
Among the network nodes that store location information a set of network nodes related to the second subarea LAI can store location information comprising an identification of the second subarea LAI.
A second network node stores an identification of a subarea of the second kind related to the mobile station MS. A central location register CLR holds an identification of the second network node related to the mobile station MS.
In the proposed method a request to handle location information is sent to the controlling network node CNl, the request comprising an identification of the mobile station MS and information from which the identification of the first subarea RAl and the identification of the second subarea LAI are derivable. The identification of the first subarea RAl is derived from the request to handle location information, preferably by the controlling network node CNl, and stored related to the mobile station MS by the controlling network node CNl. The central location register CLR is requested for the identification of the second network node. The request can comprise an identification of the mobile station MS. The request can be for example sent by the controlling network node CNl. The identification of the second network node is sent to the controlling network node CNl . A network node of the set of network nodes related to the second subarea LAI is determined according to the identification of the second network node by the controlling network node CNl . The determined network node BNl is requested to store location information, preferably by the controlling network node CNl . The request comprises an identification of the mobile station MS and the identification of the second subarea LAI. The identification of the second subarea LAI is stored related to an identification of the mobile station MS by the determined network node BNl.
An identification of the mobile station MS can be either a temporary identification or a permanent identification. A temporary identification of a mobile station MS can be translated into another temporary identification or a permanent identification e.g. according
to a rule or a look-up-table by any of the above network nodes. Likewise a permanent identification can be translated into a temporary identification.
It is advantageous that the method can be applied to a network architecture that allows larger areas in which the mobile subscriber can roam without changing the network nodes storing location information related to it. This has the advantage of a considerably lower signalling traffic transferring location information compared to the signalling traffic in a hierarchical network. Reduced signalling traffic is economically advantageous for the operator of the communication network especially if the operator is not allowed to charge signalling traffic as in a GSM-, a GPRS- or a UMTS-network. Further advantageous is that the proposed method only requires one message over the air interface for handling different kinds of location information. This is an economic use of the limited resource of radio bandwidth. This is economically advantageous for the operator, as transmission costs over the air interface are high.
If the identification of the second subarea LAI can be derived from the identification of the first subarea RAl, only the identification of the first subarea RAl has to be transmitted in the request to the controlling network node CNl. Thus the number of bits that have to be transmitted over the air interface is reduced. An example is the case that the second subarea LAI encloses the first subarea RAl. Then the identification of the first subarea RAl can be composed of the identification the second subarea LAI and an additional code.
The determined network node BNl can be for example the second network node. As the second network node already stores location information related to the mobile station MS, this reduces the signalling traffic to the determined network node BNl. Determining the second network node can also be implemented easily and is computationally efficient.
Different sets of network nodes may be related to different sets of subareas of the second kind. I.e. second subareas may exist that cannot be served by the second network node. In this case the following steps can be performed: The controlling node checks whether the
second network node belongs to the set of network nodes related to the second subarea LAI. If the second network node belongs to the set of network nodes related to the second subarea LAI, the second network node is chosen as the determined network node. If the second network node does not belong to the set of network nodes related to the second subarea LAI, the determined network node BNl is selected from the set of network nodes related to the second subarea LAI. An identification of the determined network node BNl is sent to the central location register CLR. The central location register CLR stores the identification of the determined network node BNl. It is advantageous that the method can also be applied to a network in which not all network nodes can serve a certain subarea.
The above selection of the determined network node BNl can be based on a distance to a radio network node that is related to the second subarea LAI, e.g. the geographical distance. A determined network node BNl near the radio network node reduces the transmission cost for signalling and payload traffic. A further example for the distance is the number of network nodes that are intermediary between the radio network node and the determined network node BNl i.e. a small number of intermediary network nodes reduces the needed switching capacity for signalling and payload traffic.
Further advantageous is the selection of different determined network nodes for different mobile stations in the same subarea in order to distribute the traffic load originating from a certain subarea.
In order to avoid recurrent requests of the central location register CLR for the identification of the second network node, it is advantageous to store the identification of the determined network node BNl by the controlling network node CNl. After receiving a further request to handle location information the controlling network node CNl can send a further request to store location information to the determined network node BNl of which the identification has been stored. The determined network node BNl then stores location information related to the mobile station MS. Avoiding recurrent requests to the central register reduces the transmission costs for a request to the central location register CLR.
Transmission costs are especially high if the central location register CLR is located in a different communication network which needs to be contacted by the present one.
The proposed methods can be easily implemented in an existing GPRS network. In this case the controlling network node CNl is a Serving GPRS Support Node in the GPRS network, the first subarea RAl is a Routing Area of the GPRS network, and the identification of the first subarea RAl is a Routing Area Identity.
Another application on an existing network where the proposed methods can easily be implemented is a UMTS network.
Further advantageous is the application of the proposed methods in a GSM network with a Mobile Services Switching Centre/ Visitor Location Register as the second network node, a Location Area of the GSM network as the second subarea LAI, and its Location Area Identity as the identification of the second subarea LAI.
The International Mobile Subscriber Identity (IMSI), the Temporary Mobile Subscriber Identity (TMSI), or the Packet Temporary Mobile Subscriber Identity (P-TMSI) can be easily used as an identification of the mobile station MS.
As the Home Location Register already holds identifications of MSC/ VLRs related to mobile stations it can easily be used as central location register CLR.
Further advantageous is the usage of the proposed methods during a Combined GPRS/IMSI Attach procedure or a Combined Location Area/ Routing Area Update procedure.
It is advantageous to adapt a controlling network node CNl in a way that it performs the steps of an above described method which are related to the controlling network node CNl. The controlling network node CNl comprises a reception unit for receiving messages, a processing unit for processing information and messages, and a transmission unit for sending messages. The reception unit is adapted to receive a request 1 to handle location
information, the request comprising an identification of a mobile station MS and information from which an identification of a first subarea RAl and an identification of a second subarea LAI are derivable. The processing unit is adapted to derive the identification of the first subarea RAl from the request to handle location information and to store the identification of the first subarea RAl related to the mobile station MS. The transmission unit is adapted to send a request 2 for an identification of a second network node to a central location register CLR. The reception unit is adapted to receive the identification of the second network node. The processing unit is adapted to determine a network node BNl from a set of network nodes related to the second subarea LAI according to the identification of the second network node. The transmission unit is adapted to send a request 4 to store the identification of the second subarea LAI related to the mobile station MS to the determined network node BNl .
It is advantageous to adapt a central location register CLR in a way that it performs the steps of an above described method which are related to the central location register CLR. The central location register CLR comprises a receiver for receiving messages, a storage unit for storing identities of network nodes, a central processing unit for processing information and messages, and a transmitter for sending messages. The receiver is adapted to receive a request 2 from a controlling network node CNl that is adapted to store an identification of a first subarea RAl of a first kind for an identification of a second network node that is adapted to store an identification of a second subarea LAI of a second kind. The processing unit is adapted to retrieve the identification of the second network node from the storage unit. The transmitter is adapted to send the identification of the second network node to the controlling network node CNl .
It is easy to implement the adaptation of the controlling network node CNl or the central location register CLR using a software program controlling the controlling network node CNl or the central location register CLR.
Said software program can be distributed easily if it is stored on a computer program storage medium.
Brief description of the drawings
Fig. 1 shows the structure of a location area that is composed of different routing areas.
Fig. 2 shows an architecture and a signal flow for use of the invented method.
Detailed description of embodiments
In the following the invention is described in more detail by means of an embodiment and figures.
Figure 1 depicts the structure of a Location Area LAI that is divided into the Routing Areas RAl, RA2, and RA3. The following example describes the application of the inventive method in the context of a combined procedure for updating location information of a mobile station MS that is connected to a GPRS network and a GSM network at the same time. The procedure can be a part of a Combined Routing Area/ Location Area Update Procedure or part of a Combined GPRS/ IMSI Attach Procedure. The coverage area of the GSM network is divided into Location Areas and the coverage area of the GPRS network is divided into Routing Areas. Each Location Area is divided into one or more Routing Areas. Routing Area Identities are used for identifying Routing Areas and Location Area Identities are used for identifying Location Areas. A Routing Area Identity is a code that is composed of a Location Area Identity plus a Routing Area Code. Thus the Location Area Identity can be derived from the related Routing Area Identity. Each Location Area is divided into one or more Routing Areas, so that an update of the Location Area Identity can be triggered by an update of the Routing Area Identity.
Figure 2 depicts a mobile station MS in a communication network that is connected to a network node CNl via a radio network node RN. The identity of the Routing Area the mobile station MS is in can be stored related to the mobile station by the network nodes CNl, CN2, and CN3. The network nodes BNl, BN2, and BN3 are related to the Location
Area the mobile station MS is in. The Central Location Register CLR, holds an identification of a network node related to the mobile station. The proposed method comprises a sequence of messages and processing steps. The messages exchanged between the network nodes respectively between the network nodes and the mobile station are depicted as arrows.
In order to be able to page the mobile station in the Routing Area it is in, a Routing Area Identity is stored in a Serving GPRS Support Node (SGSN) related to the mobile station MS. In the same way a Location Area Identity is stored in relation to the mobile station by a Mobile Services Switching Centre/Visitor Location Register (MSC/VLR). Sets of SGSNs and sets of MSC/VLRs are pooled resources for sets of Location Areas and sets of Routing Areas respectively. The network nodes CNl, CN2 and CN3 belong to the set of SGSNs related to the Routing Area RAl. The network nodes BNl, BN2 and BN3 belong to the set of MSC/VLRs related to the Location Area LAI. An identification of the MSC/VLR related to the mobile station is stored by a Central Location Register CLR, e.g. an HLR.
The method is applicable to a Combined Routing Area/ Location Area Update as well as to a Combined GPRS/ IMSI Attach. The request 1 is a Combined Routing Area/ Location Area Update Request in the first case and a Combined GPRS/ IMSI Attach Request in the latter case.
First the Scenario of a Combined GPRS/ IMSI Attach according to the proposed method shall be described. The mobile station MS has been roaming in detached mode and thereby entering a new Routing Area RAl . In order to attach to both the GPRS network and the GSM network the mobile station initiates a Combined GPRS/ IMSI Attach. If the new Routing Area RAl is related to the same set of SGSNs as the old Routing Area, a Combined GPRS/ IMSI Attach Request 1 is sent to that SGSN which stores the old Routing Area Identity related to the old Routing Area the MS has been in. The request 1 comprises the Routing Area Identity RAIL The request 1 is sent via the radio network node RN that is related to the new Routing Area RAl. If the new Routing Area RAl cannot be served by
the SGSN that stores the old Routing Area Identity, the radio network node RN selects a new SGSN among the set of SGSNs related to the Routing Area RAl and the Combined GPRS/ IMSI Attach Request 1 is sent via the radio network node RN to the selected SGSN. The SGSN to which the Combined GPRS/ IMSI Attach Request 1 is sent is referred as network node CNl .
In the scenario of Combined Routing Area/ Location Area Update the mobile station MS is attached to both the GPRS network and the GSM network and the mobile station MS is entering the new Routing Area RAl. If the new Routing Area RAl is related to the same set of SGSNs as the old Routing Area, a Combined Routing Area/ Location Area Update Request 1 is sent to that SGSN which stores the old Routing Area Identity related to the old Routing Area the MS has been in. The request 1 comprises the Routing Area Identity RAH. The request 1 is sent via the radio network node RN that is related to the new Routing Area RAl . If the new Routing Area RAl cannot be served by the SGSN that stores the old Routing Area Identity, a radio network node RN that is related to the new Routing Area RAl selects a new SGSN among the set of SGSNs related to the Routing Area RAl and the Combined Routing Area Location Area Update Request 1 is sent via the radio network node RN to the selected SGSN. The SGSN to which the Combined Routing Area/ Location Area Update Request 1 is sent to is referred as network node CNl.
The Routing Area Identity RAIl is composed of a Location Area Identity LAI1 and a Routing Area Code RACl . The Routing Area Identity RAIl is stored related to the IMSI related to the mobile station MS by the network node CNl. The request 1 additionally comprises either the Packet Temporary Mobile Subscription Identity (P-TMSI), related to the mobile station or the International Mobile Subscriber Identity (IMSI) related to the mobile station. If the request has comprised the P-TMSI related to the mobile station MS, the network node CNl translates the P-TMSI related to the mobile station into the IMSI related to the mobile station.
The network node CNl sends a request 2 for the ISDN number E.164 of the MSC related to the mobile station MS and the ISDN number E.164 of the VLR related to the mobile station MS to the Central Location Register CLR that is related to the mobile station. The request comprises the IMSI related to the mobile station. The ISDN number E.164 of the MSC related to the mobile station MS shall be referred to as MSC address and the ISDN number E.164 of the VLR related to the network node BNl shall be referred to as VLR number. The Central Location Register CLR responds to the network node CNl with a message 3 comprising the MSC address and the VLR number of the network node BNl.
The messages 2 and 3 can be the request and the response of a new MAP message according to the Mobile Application Part (MAP) specification ETSI TS 100 974 V7.5.0 of the Global System for Mobile Communications (GSM). An example for such a new MAP message is described in table 1. The new MAP message can either be a request 2 from the network node CNl to the Central Location Register CLR, an indication from the Central Location Register CLR to the network node CNl, the response 3 to said request from the Central Location Register CLR to the network node CNl, or a confirmation from the network node CNl to the Central Location Register CLR. In the first column the parameters according to the MAP specifications ETSI TS 100 974 V7.5.0 of the GSM that are contained in the messages request, indication, response, and confirm are listed. The entries in the table indicate, which of the parameters are transmitted with the messages related to the respective column. Mandatory parameters are marked with M, conditional parameters are marked with C. Parameters of which the inclusion is an option of the service provider of the Central Location Register CLR is marked with O. The entry (=) indicates that the parameter transmitted in the related message should be identical to the parameter that is specified in the column left of the entry (=).
In an alternative embodiment the request only comprises an Invoke Id and the IMSI and the response only comprises said Invoke Id and the VLR number.
Tab. 1 : Proposed MAP message
After the reception of the message 3 the network node CNl checks whether the MSC/VLR whose VLR number was returned by the Central Location Register CLR belongs to the set of MSC/VLRs related to the Location Area LAI . If the MSC/ VLR whose VLR number was returned by the Central Location Register CLR belongs to said set of MSC/ VLRs, a Location Update Request 4 is sent to this MSC/ VLR. In order to address the MSC/VLR, the VLR number that has been returned by the Central Location Register CLR is translated to a Pointcode according to the CCITT Signalling System No. 7. If the MSC/ VLR does not belong to said set of MSC/ VLRs, a MSC/ VLR that belongs to said set of MSC/ VLRs is chosen according to a load distribution algorithm and the Location Update Request 4 is sent to the chosen MSC/ VLR. The MSC/ VLR to which the Location Update Request 4 is sent is referred to as network node BNl. The Location Update Request 4 comprises the Location Area Identity LAI1 and the IMSI. If a new MSC/ VLRs has been chosen, a new Temporary Mobile Subscriber Identity (TMSI) related to the mobile station is assigned. In order to be able to send a further Location Update Request to the MSC/ VLR related to the mobile station without asking the Central Location Register CLR for the VLR number and the MSC address, the received VLR number and the MSC address that have been returned by the Central Location Register CLR respectively the VLR number and the MSC address relating to the chosen MSC/VLR are stored by the network node CNl .
The network node BNl sends a Location Update Accept message 5 back to the network node CNl. The message 5 can optionally comprise the new TMSI.
In the case of Combined Routing Area/ Location Area Update Procedure the mobile station MS is informed that location information was correctly updated by sending a Routing Area Update Accept message to the mobile station MS. In the case of a Combined GPRS/ IMSI Attach Procedure, the mobile station MS is informed that the procedure was successful in an Attach Accept message. Both the Routing Area Update Accept message and the Attach Accept message are depicted as message 6.
The above embodiment admirably achieves the object of the invention. However, it will be appreciated that departures can be made by those skilled in the art without departing from the scope of the invention which is limited only by the claims.