NO313028B1 - Assigning identities in non-hierarchical cellular networks - Google Patents

Description

Technical area

This invention finds application in mobile telephone networks.

Background

Today, the nodes in a mobile system are organized in a hierarchical way. The location and routing areas are controlled by an RNC (Radio Network Controller) and each RNC is controlled by an MSC (Mobile System Controller) and an SGSN (Serving GPRS Support Nodes), see Figure 2.

The MSC node is used for voice and circuit-switched data traffic, and the SGSN node is used for packet-switched data traffic.

The mobile user in such a system is identified by a temporary identity, which is assigned to the user by the MSC and the SGSN. These two temporary identities are handled separately. The MSC handles the TMSI (Temporary Mobile Subscriber Identifier) parameter and the SGSN handles the P-TMSI (Packet Temporary Mobile Subscriber Identity). The TMSI/P-TMSI is only valid in the domain of an MSC/SGSN.

When the mobile user moves from a routing area controlled by one SGSN to another routing area controlled by another SGSN, the user will perform a "routing area update procedure" see Figure 4. In this procedure, the mobile user will inform the new SGSN of its old routing area and its old P-TMSI. The new SGSN will then see that this routing area is covered by another SGSN. The new SGSN will then contact the old SGSN, with a message containing the old RAI (Routing Area Identifier) and the old P-TMSI, to obtain information about the mobile user.

The key for this system to work is that each routing area is covered by only one SGSN.

For users associated with the circuit-switched domain, the procedure is exactly the same except that the terms "location area", "MSC" and "TMSI" are used instead of "routing area", "SGSN" and "P-TMSI".

When a user switches off his phone, he will be disconnected from the network. When the user switches on their phone again, a connection procedure will be initiated (figure 5). This procedure is equivalent to "location/routing area update" in the way that the mobile user informs the MSC/SGSN that he wants to connect and gives his old TMSI/P-TMSI and location/routing area, and the new MSC/SGSN will contact it

old MSC/SGSN to get user information.

In the future we will have mobile networks that are not organized in a hierarchical way. For these networks, all MSCs and SGSNs are placed in pools and all MSCs/SGSNs will be able to serve all RNCs. Since the MSCs/SGSNs can serve all the RNCs they can also serve all location/routing areas, see Figure 2. A network organized in this non-hierarchical way is also called a "Pooled MSC/SGSN network".

When a mobile user moves into or joins a location/routing area, the RNC will select one of the MSCs/SGSNs to handle this mobile user. The algorithm the RNC uses for this selection is outside the scope of this invention.

Problem

When a mobile user moves to a new location/routing area he will start the "location/routing area update procedure" (Figure 4). If the network is built up in a non-hierarchical way, the RNC will select one of the MSCs/SGSNs. This new MSC/SGSN will then receive information about the user's old TMSI/P-TMSI and the old location/routing area. The problem for this new MSC/SGSN is that it cannot determine which MSC/SGSN served this mobile user previously. It is not even possible for the new MSC/SGSN to detect whether the mobile user was associated with the same MSC/SGSN previously. The same problem also occurs when the user connects to a network.

Known solutions

Known solution number 1 is to introduce a new parameter in the system called "Core Network Element Identity", which identifies the MSCs and SGSNs. If the mobile user includes this new identity in the message sent from the mobile, the MSC/SGSN is able to find out which MSC/SGSN served this mobile user previously.

However, this introduces a new parameter in the messages passing between the MSC/SGSN and the mobile user. The user equipment must therefore be updated. Since a number of mobile phones will be on the market before this new parameter is introduced, this solution is not suitable.

Known solution number 2 to the problem is to make the TMSI/P-TMSI unique within a PLMN (mobile network) and that each MSC/SGSN only has a given range of the total TMSI/P-TMSI. If the mobile user initiates a "location/routing area update procedure", the new MSC/SGSN will see that the TMSI/P-TMSI belongs to another MSC/SGSN and can then contact the old MSC/SGSN to obtain the information about the mobile the user.

The disadvantage of solution number 2 is that it limits the number of mobile users that can connect to a PLMN since the TMSI/P-TMSI must be unique within an entire PLMN and is only 32-bit long. The limitation should not be a problem today, but with an increasing number of machine-to-machine communications this may be a problem in the future. In addition, the operator can use one or more bits in the TMSI/P-TMSI to indicate whether there has been a restart in the MSC/SGSN.

Concise summary of the invention

The problems outlined above are solved by an arrangement according to the present invention.

In this arrangement, each MSC/SGSN is allowed to use the full range of TMSI/P-TMSI and allocate specific subsets of said TMSI/P-TMSI for use in each LA/RA. This allocation is specific to each MSC/SGSN. This means that the MSC/SGSNs will share the available TMSI/P-TMSI in an LA/RA between them. In a different LA/RA, the TMSI/P-TMSI will be shared according to a different ratio. In this way, an MSC/SGSN that receives TMSI/P-TMSI and LAI/RAI from an MS during, for example, an association procedure, can determine the identity of the old MSC/SGSN by comparing the two identifiers. At the same time, the full range of TMSI/P-TMSI is available for use, distributed among the MSC/SGSNs.

For an exact definition of the scope of the invention, reference is made to the attached patent claims.

Brief description of the drawings

Figure 1 is a table showing how P-TMSIs are distributed in four different RAs served by three SGSNs. The P-TMSIs are distributed according to the inventive method. Figure 2 is a schematic image of a mobile network of today where the LA/RAs are organized in a hierarchical relationship with the MSC/SGSNs. Figure 3 is a schematic image of the solution that is now emerging, where the MSC/SGSNs are organized in a park and together serve all LAs/RAs. Figure 4 is a diagram showing the individual steps performed during an RA update. Figure 5 is a diagram showing the steps in an attachment procedure.

Detailed description of the invention

Reference is made to Figure 2, which shows the hierarchical organization of today's mobile phone network. Each LA/RA is assigned a specific MSC/SGSN. There is therefore no doubt as to which MSC/SGSN a particular LA/RA belongs to. '

If a mobile user in a mobile network detects that he has moved to another routing area (Figure 4), he will inform the SGSN serving the new RA by issuing a message, 1. The old RAI and P-TMSI will be included in this message. Information about the new RAI is included by the new RNC.

When the new SGSN receives the message, it detects from the RAI that this mobile user was previously associated with another SGSN. The old SGSN is therefore contacted, 2, to obtain information about this user. The old P-TMSI and old RAI are included in the message to the old SGSN. The procedures for updates to the other nodes in the network have been omitted from the figure.

In step 4, the mobile user is informed that it has been associated with another RA and given a new P-TMSI valid for this SGSN.

Figure 5 shows the connection procedure for a mobile user. This procedure is in many ways similar to the RA update procedure described above.

When the mobile user switches on his phone, a message is issued to inform the SGSN that he wishes to associate, step 1.

In this particular case, when the SGSN receives the message it detects from the RAI that this mobile user was previously associated with another SGSN. The old SGSN is therefore contacted for information about this user, step 2. The old P-TMSI and old RAI are included in the message to the old SGSN.

In step 4, the mobile user is informed that he has been associated with another RA and given a new P-TMSI that is valid for this SGSN.

If these procedures are performed in a hierarchically organized network, it will be very easy for the new SGSN to find the identity of the old SGSN, as this information can be determined directly from the P-TMSI.

Figure 3 shows a modern mobile network where the SGSNs are organized in a park. This means that if a mobile station, for example, enters a new routing area, the RNC will pick an SGSN from the park and design it to serve the mobile station. When an SGSN is given a new mobile station, it must find out which SGSN has previously served the mobile station, in order to retrieve information regarding the mobile station. The problem is that the new SGSN cannot derive this from the P-TMSI.

According to the present invention, the solution to the problem is to let each MSC/SGSN use the full range of TMSI/P-TMSI, and then only use part of the TMSI/P-TMSI in each location/routing area. The manner in which each MSC/SGSN distributes the TMSI/P-TMSI range between each location/routing area must be coordinated so that no TMSI/P-TMSIs overlap within a location/routing area.

Figure 1 shows an example where the P-TMSI is in the range 0-OxFFFFFFFF and the different RAIs are named a,b,c and d. In this example, each SGSN assigns the same number of P-TMSIs to each routing area, but this is not necessary. The important thing here is that no P-TMSIs overlap within a routing area or within an SGSN.

A problem with this solution arises when the RAI-SGSN matrix needs to be changed, for example after a new SGSN is introduced. If a mobile user is given a P-TMSI before a change to the RAI-SGSN matrix, and then tries to re-associate using the old P-TMSI, it must be possible for the network to detect that this was an old P - TMSI. One way to do this is to designate one or more of the bits as audit bits. These revision bits must be updated every time the RAI-SGSN matrix changes. One way to do this could be to let the last two bits in the TMSI/P-TMSI be the revision bits. The first time the operator creates the RAI-SGSN matrix he will set the two revision bits to "00". After a change in the RAI-SGSN matrix, the two revision bits are set to "01". If a mobile user tries to associate after the change of the RAI-SGSN matrix, the SGSN will detect that it should use the old matrix to determine which SGSN handled this user previously.

This problem is of course also valid for the MSC and the location domain.

Benefits

The advantages of the new solution compared to the known solution number 1 is that it is possible to keep the temporary mobile identities and location/routing area identities we have today if we change the network to a non-hierarchical network. It will also have the advantage that it is not necessary to change the mobile phones.

The advantages of this solution compared to known solution number 2 is that the number of subscribers who can connect to a PLMN is not limited by the range of TMSI/P-TMSI-! parameters.

Concepts and abbreviations Abbreviations

GPRS General Packet Radio Service

LA Location Area

LAI Location Area Identifier

MSC Mobile Services Switching Centre

P-TMSI Packet Temporary Mobile Subscriber Identity RA Routing Area

RAI Routing Area Identifier

RNC Radio Network Controller

SGSN Serving GPRS Support Node

TMSI Temporary Mobile Subscriber Identity

Concepts

LA A geographic area covered by an RNC.

The location area is used for circuit-switched services.

LAI Each location area is identified by a location area identifier. This identity consists of 6 decimal numbers and a 16-bit binary value. An LAI is unique worldwide.

MSC Node in the mobile network that handles the mobility processing and call processing for circuit-switched services (voice and circuit-switched data).

PLMN This is the mobile network managed by an operator.

P-TMSI Same as TMSI except that it is assigned by the SGSN

and that it is unique within the routing areas covered by

SGSN.

RA A routing area is the same as a location area except that it is used for packet-switched data services. An RA and an LA can cover the same geographical area.

RAI A Routing Area Identifier is the same as an LAI except that it has an 8-bit binary value in addition to the values in the LAI. An RAI is unique worldwide.

RNC Node in the mobile network that handles the radio traffic and radio resources towards the mobile user.

SGSN Node in the mobile network that handles mobility and session processing for packet-switched data services.

TMSI This is a temporary 32-bit identity used to identify the mobile user. The TMSI is assigned to the mobile user by the MSC. Each TMSI is unique within the location areas covered by the MSC.

Claims (4)

1. Arrangement in a mobile telephone network, where said network includes a park of MSC/SGSN (Mobile Switching Centres/Serving GPRS Support Nodes) serving an MS (Mobile station), said MS being located in an LA/RA (Location Area /Routing Area), which LA/RA is identified by a LAI/RAI (Location Area Identifier/Routing Area Identifier) and where the MS is identified by a P-TMSI/TMSI (Packet Temporary Mobile Subscriber Identity/Temporary Mobile Subscriber Identity), wherein said MSC/SGSNs are controlled by a number of RNCs (Radio Network Controllers) which are arranged to assign an MSC/SGSN to serve the MS by selecting an available MSC/SGSN from said park of MSC/SGSNs -is, characterized in that for a particular RAI each MSC/SGSN is given a unique sub-area of the TMSI/P-TMSI from which MSCs within this LAI/RAI can be assigned TMSI/P-TMSIs. 2. Arrangement according to claim 1, characterized in that each MSC/SGSN is allowed to use the full range of TMSI/P-TMSIs. 3. Procedure in a mobile network, where a mobile station is assigned an MSC/SGSN from a pool of available MSC/SGSNs, characterized in that each MSC/SGSN is arranged to issue TMSI/P-TMSI from the full range of available TMSI/P-TMSIs and allocate dedicated subareas for use in the individual LA/RAs. 4. Method according to claim 3, where the mobile station performs an LA/RA update or association procedure and issues a message containing the old LAI/RAI and old TMSI/P-TMSI, characterized by the new MSC/SGSN requesting confirms the identity of the old MSC/SGSN from a comparison of said LAI/RAI and TMSI/P-TMSI.