SE515477C2 - Interface configuration procedure between a serving GPRS support node and a base station system - Google Patents

Abstract

The present invention is related to a method of configuring an interface between a serving GPRS support node and a base station system. Allocation (401) of a new network service entity identifier is requested. In response to said request, a new network service entity identifier is automatically allocated (402) according to a predefined rule ensuring that the new network service entity identifier is unique within the serving GPRS support node. Data structures in the serving GPRS support node and the base station system are automatically initiated (403) by registering the allocated new network service entity identifier in said data structures.

Description

25 515 477 f: a =. . ». . . . . 2 SUMMARY OF THE INVENTION The present invention is directed to the problem of providing a more efficient way of configuring an interface between a serving GPRS support node and a base station system, and in particular such an interface utilizing IP-based communication.

The problem is essentially solved by a procedure in which a new Network Service Entity Identifier is allocated automatically and automatically registered in data structures in the serving GPRS support node and the base station system.

More specifically, the problem is solved in the following way. In response to a request for the allocation of a new network service identifier, the new network service identifier is automatically allocated according to a predetermined rule that ensures that the new network service identifier is unique within the serving GPRS support node. Said data structures in the serving GPRS support node and the base station system are automatically initiated by registering the allocated new network service unit identifier in said data structures.

A general object of the invention is to provide a more efficient way of configuring an interface between a serving GPRS support node and a base station system, and in particular such an interface utilizing IP-based communication.

A more specific object of the invention is to provide a method of configuring the interface between a base station system and a serving GPRS support node whereby a new network service unit identifier is automatically allocated and registered in both the base station system and the serving GPRS support node. Yet another object of the invention is to provide a method of configuring the interface between a base station system and a serving GPRS support node whereby not only a new network service unit identifier is automatically allocated and registered in data structures in both the base station system and the serving GPRS support node but also the need for a new network service identifier are automatically detected.

A general advantage offered by the invention is that it provides a more efficient way of configuring an interface between a serving GPRS support node and a base station system, and in particular such an interface utilizing IP-based communication.

A more specific advantage offered by the invention is that it frees operation and maintenance personnel from the tasks of allocating new network service identifiers and ensuring that said identifiers are unique within the serving GPRS support node as well as registering the new network service identifiers in both base station systems. and the operating GPRS support node.

The invention will now be described in more detail with reference to exemplary embodiments thereof and also with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view illustrating the configuration of a PLMN supporting GPRS.

Fig. 2 is a block diagram showing the current Gb interface between SGSN and BSS.

Fig. 3 is a block diagram showing a modified Gb interface between SGSN and BSS that supports IP.

Fig. 4 is a fate diagram showing a basic method according to the invention.

Fig. 5 shows an exemplary cellulite network in which the present invention is applied.

Fig. 6 is a signal diagram showing configuration of a packet data cell. Fig. 7 is a block diagram illustrating an entry for administrative area data in a radio network server.

Fig. 8 is a block diagram showing a cell configuration data record in a radio base station.

Fig. 9 is a block diagram showing an NSEI data record in a network port.

Fig. 10 is a block diagram showing an SGSN-NSEI data record in an SGSN.

DETAILED DESCRIPTION OF THE EMBODIMENTS General packet radio service (GPRS) is a standard from the European Telecommunications Standards Institute (ETSI) for packet data in GSM systems. GPRS has also been accepted by the Telecommunications Industry Association (TIA) as the packet data standard for TDMA / 136 systems. By adding GPRS functionality to the public land mobile network (PLMN), operators can give their subscribers resource-efficient access to external Internet Protocol-based (IP) networks.

GPRS offers air interface transfer speeds up to 115 kbit / s depending on mobile terminal capacity and carrier interference. Even higher transmission speeds will be available when the so-called EDGE technology, i.e. Increased data rates for GSM and TDMA / 136 development are introduced. Furthermore, GPRS allows your users to share the same air interface resources and allows operators to charge customers for wireless services based on the amount of data transmitted instead of uptime.

Fig. 1 illustrates the configuration of a public land mobile network (PLMN), i.e. a cellular network, which supports GPRS. Compared to a traditional GSM network, GPRS introduces two new nodes for handling packet data traffic, the Serving GPRS Support Node (SGSN) and the Gateway GPRS Support Node (GGSN). These nodes interact with the Home Location Register (CPR), the Mobile Services Switching Center / Visitor Location Register, MSC / VLR) and the Base Station System (BSS).

GGSN, which is the connection point for packet data networks, is connected to SGSN via an IP backbone. User data, for example from a GPRS terminal to the Internet, is transmitted encapsulated over the IP backbone network.

SGSN in turn is connected to BSS and is on the same hierarchical level in the network as MSC / V LR. It keeps track of the position of the GPRS user, performs security actions and manages access control, ie. to a large extent, it does for the packet data service what the MSC / VLR does for the circuit-switched service.

Fig. 2 illustrates the so-called The Gb interface that connects BSS and SGSN and allows the exchange of signaling information and user data.

Starting at the top in fi g. 2, the logical link control protocol layer (Logical Link Control, LLC) 201 provides a reliable logical link between SGSN and mobile stations operating in the area served by SGSN, ie. SGSN area. The LLC protocol 201 terminates in the mobile stations and SGSN and is thus transparent to the BSS.

The primary function of the BSS GPRS Protocol (BSSGP) layer 202 is to provide the radio quality of service and routing information needed to transmit user data between the BSS and the SGSN. In the BSS, it acts as an interface between Logical Link Control (LLC) protocol data devices, ie. LLC frames, and Radio Link Control / Medium Access Control (RLC / MAC) blocks. In the SGSN, it forms an interface between RLC / MAC-derived information and LLC frameworks. Further details are if the BSSGP layer 202 is found again in the GSM OSJS specification. 10 15 20 25 30 515 477 6 The Network Service (NS) 203 implements the link layer of the OSI model. The NS layer is based on Frame Relay (FR) and provides network service to the BSS GPRS protocol layer (BSSGP). It allows sequential transmission of BSSGP Protocol Data Units (PDUs) in an unreliable manner, i.e. PDUs can be lost and the proper order of PDUs cannot be maintained in exceptional circumstances. Further details on the network layer 203 can be found in the GSM 08.16 specification.

The physical layer 204 may be implemented using, for example, an E1 or T1 transmission line.

In a PLMN that supports GPRS, SGSN and GGSN nodes are connected by an IP network, while SGSN and BSS nodes are currently connected by a Frame Relay network. Consequently, the network operator needs to build, operate and maintain both an IP network and a Frame Relay network. It would be preferable for the network operator to only need to implement one IP network and it would thus be advantageous to add IP support to the Gb interface.

In order to minimize the impact on existing functions when IP support is added to the Gb interface and to allow coexistence of IP-based and Frame Relay-based Gb interfaces, it is desirable to modify the BSSGP protocol layer as little as possible and thus preferably not at all. need to modify your BSSGP protocol layer.

In the BSSGP protocol layer, a key concept is the so-called BSSGP Virtual Connections (BVCs) that provide communication paths between BSSGP functional units. Each BVC is used to transport BSSGP PDUs between peer-to-peer (PTP) function units, peer-to-peer (PTM) function units, and peer signaling function units. 10 15 20 25 30 515 477 t, .n A PTP function unit is responsible for transmitting PTP user data. There is only one PTP function unit per cell.

A PTM ~ ing unit is responsible for transmitting PTM user data. There is only one PTM functional unit per network service unit and there is one or more network service units per BSS.

A signaling unit is responsible for other functions, e.g. search. There is only one signaling unit per network service unit and there is one or your network service units per BSS.

Each BVC is identified by a BSSGP Virtual Connection Identifier (BVCI) that has an end-to-end signal across the Gb interface. Each BVCI is also unique within two equal network service entities (Network Service Entities, NSEs) in the network protocol layer. Each network service is identified by a Network Service Entity Identifier (NSEI). The NSEI together with the BVCI uniquely identifies a BSSGP virtual connection in an SGSN. The BVCI value zero identifies a BSSGP virtual connection that provides communication between peer signaling function units, the BVCI value one identifies a BSSGP virtual connection that provides communication between peer-to-peer PTM functional units while BVCI values greater than one identify BSS virtual connections - handles communication between peer-to-peer PTP functional units.

To minimize the impact on the BSSGP protocol layer when adding IP support, it is important to maintain the BVC concept and since unique identification of a BVC requires a combination of both a BVCI and an NSEI, the Gb interface must continue to support the use of BVCI and NSEI. Fig. 3 shows an exemplary embodiment of a modified Gb interface that supports IP while maintaining the BVC concept.

The LLC protocol layer 201 and the BSSGP protocol layer 202 are identical to the corresponding protocol layers in fi g. 2.

A new protocol layer, Network Service over IP (NSOIP) 303, replaces the original NS protocol layer 203. The NSOIP protocol layer 303 is arranged to provide basically the same service to the BSSGP protocol layer 202 as the original NS protocol layer 203 but based on the services offered by the underlying IP-based communication services instead of Frame Relay.

The NSOIP protocol layer can thus be considered as an NS protocol layer emulator.

The NSOIP protocol layer 303 implements a set of PDUs corresponding to each of the PDUs implemented by the original NS protocol layer 203, but the PDUs implemented by the NSOIP protocol layer 303 all include an additional NSEI information element. Another difference, compared to the original NS protocol layer 203, is that the NSOIP protocol layer 303 implements an ordering mechanism to ensure that NSOIP PDUs exchanged between two equal devices are received in the same order in which they were sent. The NSOIP protocol could alternatively be run on top of the Transmission Control Protocol (TCP) and since TCP ensures that data is received in the same order in which it was transmitted, the NSOIP protocol would then not need to implement an ordering mechanism.

The protocol layers 304-306 below the NSOIP protocol layer 303 are all in accordance with the well-known IETF architecture. The User Datagram Protocol (UDP) is used in the transport protocol layer 304, the Internet Protocol (IP) is used in the Internet layer 305, and the physical layer 306 may be based on, for example, ATM or SDH / SONET. 10 15 20 25 30 515 477 9 A problem with the existing Frame Relay-based Gb interface is that the configuration of network service virtual connections is performed using administrative means, ie. requires manual intervention. In particular, operation and maintenance personnel manually determine when there is a need to allocate a new NSEI value and also by manual procedures must ensure that the new NSEI value will be unique within the SGSN. This is an extremely cumbersome procedure, especially if different organizations are responsible for the operation and maintenance of the SGSN and the respective base station system.

The present invention is directed to the problem of providing a more efficient way of configuring the (lb interface, and in particular a Gb interface using IP based communication.

Fig. 4 illustrates the base method according to the invention for configuring an interface between a serving GPRS support node and a base station system in a communication network supporting general packet radio service.

At step 401, the allocation of a new network service identifier is requested.

In response to said request, a new network service identifier is automatically allocated at step 402 according to a predetermined rule which ensures that the new network service identifier is unique in the serving GPRS support node.

Data structures in the operating GPRS support node and the base station system are automatically initialized at step 403 by registering the allocated new network service unit identifier in said data structures.

The basic method according to the invention provides an automatic procedure for allocating a new, SGSN-unique, NSEI value and making the new NSEI value known in both the SGSN and the base station system. 10 15 20 25 30 515 477 .f f »- 10 The step of requesting the allocation of a new network service identifier can be initiated in response to an explicit request from the operation and maintenance staff to allocate a new network service identifier. However, in preferred embodiments of the invention, the step of requesting allocation of a new NSEI is initiated automatically when a need for allocation of a new network service identifier is automatically detected in connection with the configuration of new packet data cells in the base station system.

Fig. 5 illustrates an exemplary embodiment of a cellular network 501 that supports GPRS to which the present invention is applied. The cellular network 501 includes an SGSN node 502, an IP network 503 and a base station system 504.

The base station system 504 includes a gateway (GW) 505, a lookup server 506, a radio network server (RNS) 507, a subnetwork manager (SNM) 508 and three radio base stations (Radio Base Stations). RBS: er) 509-511. The SGSN node 502 and all the nodes 505-511 in the base station system 504 are all connected to the IP network 503, i.e. all communication between the different nodes in fi g. 4 is IP based.

The subnet manager 508 is an operation and maintenance node that enables the cellular network operator to manage all equipment within the base station system 504.

The radio network server 507 handles traffic control functions, e.g. distribution of search and allocation of resources for deletion (fl ush), within the base station system 504. Among the data information stored in the radio network server 507 there are data structures which contain data information related to administrative areas which have been de- nied in the base station system 504.

An administrative area is a grouping of cells that are all associated with one and the same NSEI, ie. the BVCs associated with the cells in the administrative region are all identified by the same NSEI value. It is up to the network operator to determine how cells should be grouped into administrative areas. An administrative area can, for example, correspond to one or fl your location areas or routing areas. If additional radio network servers are added to the base station system 504, each radio network server may be defined to serve one or more of the administrative areas designated to provide an appropriate load distribution on the various radio network servers. The network operator may also decide to define the administrative areas according to a plan that makes each administrative area a suitable area of responsibility for allocation to a specific unit within the network operator's operation and maintenance organization.

Fig. 7 illustrates an exemplary data structure used in the radio network server 507 to hold data information related to an administrative area. The administrative area data entry 701 includes an identity field 702 for storing the identity of the administrative area, an NSEI field 703 for storing an NSEI value associated with the administrative area and a list 704 of BVCI values for storing the BVCI values. defined for the administrative area.

Each of the radio base stations 509-511 can serve one or more of your cells. Each radio base station includes transceivers for transmitting radio signals to and receiving radio signals from mobile stations operating in the cells served by the radio base station. The functions performed by radio base stations 509-511 include RLC / MAC management and channel coding.

Among the data information stored in each radio base station 509-511 are data structures including configuration data related to each cell served by the radio base station. Fig. 8 illustrates an exemplary data structure used in radio base stations 509-511 for storing cell configuration data. The cell configuration data record 801 includes an NSEI field 802, a BVCI field 803, a cell identity field 804, a location area identity field 805, a routing area identity field 806. The NSEI field 802 together with the BVCI field BVC identifies is associated with the cell.

All communication between the base station system 504 and the SGSN node 502 passes through the network port 505. The network port 505 is responsible for performing signal format conversion between a signal format used for internal signaling in the base station system 504 and the signal format used for signaling in the Gb interface between the base station system 504 and the SGSN node 502. For signals, i.e. messages, transmitted from the SGSN node 502 to the base station system 504, the network port 505 implements a signal allocating function which, based on BVCI and NSEI values embedded in signals from the SGSN node 502, distributes the information in the signals to the radio network server 507 or one of the radio base stations 509-511. Among the data information stored at the mains port 505, there are data structures containing data information related to how the signals received from the SGSN node 502 are to be distributed. Fig. 9 illustrates an example of a possible signal distribution data structure. The NSE1 record 901 includes an NSEI field 902 and a list 903 of defined BVCI values and associated IP addresses, each defined BVCI value being associated with an IP address of either the radio network server 507 or one of the radio base stations 509. 511.

The NSEI register 901 thus controls to which node the network port 505 distributes information received from the SGSN node 502.

The lookup server 506 implements various lookup functions similar to the Domain Name System (DNS) LETF. It provides, for example, translation between host names of different nodes in the base station system 504 and IP addresses assigned to the nodes.

Note that only elements deemed necessary to illustrate the present invention are found in Fig. 5 and that thus a cellular radio communication network, to which the invention is applied, may comprise a larger number of the node types illustrated in Figs. As well as other types of nodes such as network port GPRS support nodes, home location registers, etc.

Fig. 6 illustrates the signaling sequence in an exemplary scenario showing a first embodiment of a method according to the invention.

The scenario begins when a first packet data cell in a new administrative area within the area served by the SGSN emergency 502 is to be configured. Note that before the scenario begins, the various nodes have been configured to handle basic IP communication according to standard procedures for configuring IP network hosts.

The operation and maintenance personnel initiate configuration of the packet data cell by providing the required configuration parameters to the subnet manager 508 and ordering the subnet manager 508 to perform configuration. The subnet manager 508 sends a configuration packet data cell signal S601 to the radio network server 507. The signal includes an identification of the new administrative area, e.g. as a text string, such as “Sweden-West”, cell identity, location area identity, routing area identity, the BVCI value to be associated with the first packet data cell in the new administrative area and the identities of the radio base station, e.g. the first radio base station 509, and the radio base station antenna sector to serve the cell.

The radio network server 507 receives the configuration packet data cell signal S601 and checks whether the administrative area has previously been denominated. The radio network server 507 identifies that the administrative area is a new area and initiates an administrative area entry (see fi g. 7) to keep data information related to the administrative area. The radio network server 507 also automatically identifies that a new NSEI value needs to be allocated to the new administrative area and sends a reset BVC signal S602 to the network port 505. The reset BVC signal S602 includes a BVCI field was set to zero and an NSEI field was set to a blank value.

The NSEI blind value is a reserved value that is never assigned as an NSEI value.

For example, it can be set to the numeric value 65535. The NSEI blind value is an indication that allocation of a new NSEI value is requested.

The mains port 505 receives the reset BVC signal S602 and identifies from the NSEI blind value of the NSEI field that allocation of a new NSEI value is requested. The network port 505 initiates a new NSEI record (see fi g. 9) for the new, as yet unknown, NSEI value and enters the BVCI value zero as being associated with the IP address of the radio network server mode 507 in the new NSEI record. The network port 505 sends a BSSGP BVC reset signal S603 to the SGSN node 502. The BSSGP BVC reset signal S603 includes a BVC RESET PDU containing a BVCI information element field set to zero. The BVC-RESET PDU is encapsulated in an NSOIP UNITDATA PDU in the BSSGP BVC reset signal S603. In addition to an additional NSE1 information element field, the format of the NSOIP UNITDATA PDU is substantially similar to an NS-UNITDATA PDU as specified in GSM 08.16.

The NSEI information element field is set to the NSEI blind value.

The SGSN node 502 receives the BSSGP BVC reset signal S603 and identifies from the NSEI blank value of the NSEI information element field in the NSOlP UNlTDATA PDU portion of the signal that this signal is a request for allocation of a new NSEI value. The SGSN node 502 also identifies from the BVCI information element field that the signal is simultaneously also a request to perform the BVC reset procedure (BVC-RESET) for the signaling BVC (ie BVCI zero).

The SGSN node 502 thus automatically allocates a new NSEI value according to a predetermined rule which ensures that the new NSEI is unique in the SGSN node 502. The SGSN node 502 can, for example, select the new NSEI value by simply scanning - list the NSEI values currently in use and allocate the first NSEI value available. One skilled in the art will recognize that any other rule for allocating a unique NSEI can be used. After allocating the new NSEI value, the SGSN node 502 automatically creates a data structure to keep configuration data information associated with the new NSEI value and registers the new NSEI value and the IP address of the network port 505 in the data structure.

Fig. 10 illustrates an example of a data structure for holding data information related to an NSEI value. The SGSN NSEI data record 1001 includes an NSEI field 1002, and for each designated BVCI that has a value of two or greater (ie, the fi nth a BVC associated with a cell), there is a BVCI field 1003, a cell identity field 1004, a location area field 1005, a routing area field 1006, and an IMSI list pointer field 1007. The IMSI list pointer field 1007 points to a list of IMSI numbers 1008 representing the mobile stations currently operating in the cell associated with the BVCIIn.

After initializing the SGSN NSE1 data record 1001 for the new NSEI value, i.e. the creation of the SGSN NSEI data record 1001 and the setting of the NSEI field 1002 to the selected new NSEI value, the SGSN node 502 sends a BSSGP BVC reset acknowledgment signal S604 to the mains port 505. BSSGP BVC reset reset BV60 includes -RESET-ACK-PDU containing a BVC1 information element field set to zero. The BVC-RESET-ACK PDU is encapsulated in an NSOIP-UNlTDATA PDU in the BSSGP BVC reset acknowledgment signal S604.

The NSE1 information element field for the NSOIP UNITDATA PDU is set to the new NSEI value allocated by the SGSN need 502.

The mains port 505 receives the BSSGP BVC reset acknowledgment signal S604 and informs the new NSEI value in the previously created new NSEI record. The network port 505, together with the SGSN node 502 then performs NSOIP reset and unblocking procedures similar to the reset and deblocking procedures specified in GSM 08. 1 6. Performing NSOIP the reset procedure, the mains port 505 sends an NSOIP reset signal S605 to the SGSN node 502 and receives an NSOIP reset acknowledgment signal S606 from the SGSN node 502 while performing the NSOIP unblocking procedure, the SGSN n2 an NSOIP unblock signal S607 to the mains port 505 and receives an NSOIP unblock acknowledgment signal S608. The NSOIP PDUs involved in the NSOIP recovery and unblocking procedures all include an NSEI information element but no virtual connection identifier because the NSOIP protocol does not distinguish between different virtual connections. After performing the NSOIP reset and unblocking procedures, the new NSEI value is known and also registered as unblocked in both the base station system 504 and the SGSN node 502.

The gate 505 then sends a registration signal S609 to the retrieval server 506 and requests that the retrieval server 506 register the new NSE1 value as associated with the IP address of the gate 505. The registration signal S609 includes the new NSEI value and the gate 505 address of the gate 505. The search server 506 then performs registration accordingly.

The gate 505 also sends a reset BVC acknowledgment signal S610 to the radio network server 507. The signal includes a BVCI field set to zero and an NSE1 field set to the new NSE1 value. The radio network server 507 registers the new NSEI value in the entry for administrative area data (see fi g. 7) which was previously prepared to keep data information related to the new administrative area.

The radio network server 507 then sends a configuration cell signal S611 to the first radio base station 509. The configuration cell signal S611 includes the antenna sector identity of the radio base station, the cell identity, location area, routing area identity and the BVCI value previously received by the radio network server server signal S601. The configure cell signal S611 also includes the new NSEI value associated with the new administrative area to which the cell belongs. 10 15 20 25 30 515 477 iÉ .- 'LÉ':?; É = 17 The first radio base station 509 receives the control cell signal 611 and initiates a new cell configuration data record (see fi g. 8) with the configuration data defining the new packet data cell, i.e. cell identity, location area identity, routing area identity, BVCI value and NSEI value. The first base station 509 then sends a retrieval request signal S612 to the retrieval server 506 and requests the IP address associated with the new NSE1 value. The retrieval server 506 sends back a retrieval response signal S613 to the first radio base station 509, including the IP address of the network port 505. The first base station 509 continues to initiate a BVC reset procedure (BVC reset) by sending a reset BVC signal S602 to the mains port 505. The reset BVC signal S602 includes cell configuration data for the new cell, i.e. The NSEI value, BVCI value, cell identity, location area identity, and routing area identity were stored in the new cell configuration data record.

The gate 505 receives the reset BVC signal S602 and updates the NSEI record identified by the NSEI value in the signal with the included BVCI value and the associated IP address of the first base station 509. The gate 505 sends a BSSGP BVC reset signal S603 to the SGSN node 502. The BSSGP BVC reset signal S603 includes a BVC-RESET PDU including cell configuration data for the new cell. The BVC-RESET PDU is embedded in an NSOIP UNITDATA PDU including an NSEI information element field set to the NSEI value of the new cell.

The SGSN node 502 receives the BSSGP BVC reset signal S603 and identifies from the received NSEI value the SGSN NSEI data record (see fi g. 10) associated with the NSEI value. The SGSN node 502 updates the SGSN NSEI data record with the cell configuration data information for the new cell received in the BSSGP BVC reset signal and sends back a BSSGP BVC reset acknowledgment signal S604 to the mains port 505. 10 15 20 25 30 N 5 port 477 505 receives the BSSGP BVC reset acknowledgment signal S604. The network port identifies the IP address of the first base station 509 from the NSEI and BVCI information fields in the received signal S604 and the associated NSEI record stored in the network port 505 and sends a reset BVC acknowledgment signal S610 to the first base station 509.

The first base station 509 receives the reset BVC acknowledgment signal S610 and informs the radio network server 509 that the new cell has been configured by transmitting a configuration cell response signal S614 including the NSEI and BVCI values associated with the cell.

The radio network server 507 receives the configuration cell response signal S614 and identifies that the new cell has been configured. The radio network server 507 then sends a configured packet data cell response signal S615 to the subnet manager 508. The signal S615 includes the identity of the new administrative area and the BVCI associated with the new cell.

The subnet manager 508 receives the configuration packet data cell response signal S615 and identifies that the new cell in the administrative area has been configured correctly. The subnet manager 508 can provide an indication to the operation and maintenance personnel that the new cell has been configured correctly.

Apart from the first exemplary embodiment of the invention, set forth above, there are ways to provide rearrangements, modifications and substitutions of the first embodiment resulting in further embodiments of the invention.

Instead of requesting the allocation of a new NSEI value using a BSSGP BVC reset signal S603 including both a BVC-RESET PDU and an NSOIP 10 15 20 25 30 515 477: ïïïiíifß äfï išfäjë 19 UNlTDATA-PDU, ie. including both a request for allocation of the new NSEI value and the execution of a BVC reset procedure, separate signals could be used to request the allocation of the new NSEI value and perform the BVC reset procedure. Thus, the NSOIP protocol could include an allocate NSEI PDU and an allocate NSEI acknowledgment PDU. The gate 505 would then request allocation of a new NSEI by sending an NSOIP allocate NSEI request signal including an NSOIP allocate NSEI PDU and the SGSN node 502 would return the allocated new NSE1 value in an NSOIP allocate NSEI acknowledgment. signal including an NSOIP allocate NSEI acknowledgment PDU transporting the allocated new NSEI value in an NSEI information element. A BSSGP BVC reset signal S603 would then be sent from the network port 505 to the SGSN node 502 requesting to perform a BVC reset procedure for the BVC identified by the new NSEI value and the BVCI value zero. The internal signaling in the base station system 504 between the radio network server 507 and the radio network server 509 could remain the same as previously described in connection with fi g. 6, i.e. the network port 505 could transmit both the NSOIP allocate NSEI request signal and, upon receipt of the NSOIP allocate NSEI acknowledgment signal, the BSSGP BVC reset signal in response to receiving a reset BVC signal S602 including an NSEI blank. Alternatively, the radio network server 507 could send separate signals to the network port 505 to request transmission of the NSOIP allocate NSEI request signal and the BSSGP BVC reset signal.

Allocation of the new NSEI values can be handled either by a network service entity identifier administrator included in the operating GPRS support node or by a separate administrator mode for network service identifiers.

Different plans can be used to correlate a request signal, Lex. a BSSGP BVC reset signal or an NSOIP allocate NSEI signal, transmitted from the base station system 504 to the SGSN node 502 with a response signal transmitting an allocated new NSEI value, e.g. a BSSGP BVC reset acknowledgment signal or an NSOIP allocate NSEI acknowledgment signal, from the SGSN node 502 to the base station system 504. An alternative would be to simply restrict the radio network server 507 from initiating any requests for the allocation of new NSEIs. values until it has received confirmation that a new NSEI value has been allocated for a previous request, ie. to ensure that there is no more than one outstanding request for the allocation of a new NSEI value at any given time. Another alternative would be to introduce transaction identifiers into signals requesting the allocation of a new NSEI and the corresponding response signals. Transaction identifiers are preferably used in both the internal signals of the base station system and the signals exchanged between the base station system 504 and the serving SGSN node 502. The network port 505 may convert between the internal transaction identifier of the base station system 504 and the transaction identifier S2 between the base station exchanger and the NNS used.

The invention can of course be applied in cellular networks which have other base station system architectures than the exemplary architectures shown in fi g. 5. A possible example of an architecture for an alternative base station system would be a traditional GSM ESS architecture based on a base station controller (BSC) that controls a number of radio base stations.

Claims (7)

A method of configuring an interface between a serving GPRS support node (502) and a base station system (504) in a communication network (501) supporting GPRS, the method comprising the steps of: requesting (401) allocation of a new network service unit identifier; automatically allocate (402) a new network service identifier according to a predetermined rule that ensures that the new network service identifier is unique in the serving GPRS support node (502); automatically initialize (403) data structures (1001, 701, 801, 901) in the serving GPRS support node and the base station system (504) by registering the allocated new network service unit identifier in said data structures. . The method of claim 1, wherein said step of requesting (401) includes sending a signal (S603) to a network service unit identifier (502). . The method of claim 2, wherein the network service identifier administrator is included in the operating GPRS support node (502). The method of claim 3, wherein said signal (S603) is transmitted from the base station system (504) to the operating GPRS support node (502). . A method according to any one of claims 2-4, wherein said signal (S603) includes a network service identifier information element set to a value indicating a request for allocation of a network service unit identifier. The method of any of claims 1-5, wherein the method further comprises the step of automatically detecting a need to allocate a network service identifier and said step (401) of the request being automatically initiated upon said detection. 515 477 22 A method according to claim 6, wherein said detecting step is performed in conjunction. with the configuration of a new packet data cell in the base station system (504).