In connection-oriented switching of packet data in known mobile communications systems, resources of the transmission path between the serving node (SGSN) and the radio network subsystem (RNS) and memory resources of the radio network subsystem are reserved unnecessarily due to the burst-like nature of packet data. Thus the transmission network's limited address space and the radio network subsystem's management resources are consumed. The invention concerns such connection management in a mobile communications system, which is suitable for packet-switched data transmission. The method according to the invention is characterized in that the logical connection between the serving node (SGSN) and the radio network subsystem (RNS) is released, so that the logical connection between the serving node (SGSN) and the mobile station (MS) remains, and the released logical connection is reconnected, when relaying of user data starts.
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0. 19. A method, comprising:
releasing a first logical connection between a serving node and an access system when the first logical connection is inactive, so that a second logical connection remains between the serving node and a terminal; and
reconnecting the first logical connection between the serving node and the access system when transmission of user data begins.
0. 26. A communications system, comprising:
a connection management equipment configured to release a first logical connection between a serving node and an access system during data transmission non-activity relating to the first logical connection so that a second logical connection remains between the serving node and a terminal and configured to reconnect this first logical connection, when traffic activity starts.
10. A communications system, which is suitable for packet switched data transmission and which includes at least one serving node, at least one access system and terminals, said communications system being adapted for having a first logical connection relating to a terminal between the serving node and the access system and a second, upper-level logical connection relating to the terminal between the terminal and the serving node, the communications system comprising connection management equipment for releasing the first logical connection between the serving node and the access system during data transmission non-activity relating to the first logical connection so that the second logical connection remains between the serving node and the terminal and for reconnecting this first logical connection, when traffic activity starts.
1. A method of connection management in a communications system, which is suitable for packet switched data transmission and which includes at least one serving node, at least one access system and terminals, said communications system being adapted for having a first logical connection relating to a terminal between the serving node and the access system and a second, upper-level logical connection relating to the terminal between the terminal and the serving node, the method comprising the steps of:
releasing the first logical connection between the serving node and the access system when the first logical connection is inactive, so that the second logical connection remains between the serving node and the terminal; and
reconnecting the first logical connection between the serving node and the access system when transmission of user data begins.
2. The method of
3. The method of
4. The method of
5. The method of
6. The method of
7. The method of
preventing the release of the first logical connection between the serving node and the access system, when some unit in the communications system has such user data, which is intended for relaying over this connection.
9. The method of
11. The communications system of
monitoring equipment for identifying activity and non-activity of the user data traffic on the terminal's communication connection;
at least one timer for measuring an uninterrupted non-activity period in the relaying of user data; and
state control equipment for releasing the first logical connection between the serving node and the access system, when a pre-established time has passed as measured by the timer, and for reconnecting the first logical connection between the serving node and the access system, when the relaying of user data resumes.
12. The communications system of
13. The communications system of
14. The communications system of
resources monitoring equipment for monitoring the degree of reservation of the connection identifiers of connections between the serving node and the access system.
15. The communications system of
monitoring equipment for identifying activity and non-activity of the user data traffic on the terminal's first connection;
resources monitoring equipment for monitoring the degree of reservation of the connection identifiers of connections between the serving node and the access system; and
state control equipment for releasing the first logical connection between the serving node and the access system, when there is a shortage of connection identifiers and the connection is idle, and for reconnecting the first logical connection between the serving node and the access system, when relaying of user data resumes.
16. The communications system of
0. 20. The method of claim 19, wherein the first logical connection is released between the serving node and the access system, when terminal's communications on the first logical connection have been idle for a pre-established time.
0. 21. The method of claim 20, wherein the pre-established time is set for the connection based on the service class.
0. 22. The method of claim 19, wherein the first logical connection is released between the serving node and the access system, when a shortage of resources occurs on this transmission distance and the first connection is idle.
0. 23. The method of claim 19, wherein information on release of the first logical connection is signaled between the serving node and the terminal.
0. 24. The method of claim 19, wherein information on the need for reconnection of the first logical connection is signaled between the serving node and the terminal.
0. 25. The method of claim 19, wherein the connection of the mobility management protocol is released between the serving node and the access system, so that the connection of the upper level connection protocol between the serving node and the terminal remains.
0. 27. The communications system of claim 26, wherein the connection management equipment comprises:
a timer configured to measure an uninterrupted non-activity period in the relaying of user data; and
a state control equipment configured to release the first logical connection between the serving node and the access system, when a pre-established time has passed as measured by the timer, and to reconnect the first logical connection between the serving node and the access system, when the relaying of user data resumes.
0. 28. The communications system of claim 26, wherein the connection management equipment comprises:
resources monitoring equipment configured to monitor a degree of reservation of the connection identifiers of connections between the serving node and the access system; and
state control equipment configured to release the first logical connection between the serving node and the access system, when there is a shortage of connection identifiers and the connection is idle.
0. 29. The communications system of claim 26, further comprising:
a signaling equipment configured to signal information between the serving node and the terminal upon occurrence of at least one of a release of the first logical connection and a need for a reconnection of the first logical connection.
0. 30. The communications system of claim 26, wherein the terminal comprises a mobile station.
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This application is a continuation of international application serial number PCT/FI99/00564, filed 24 Jun. 1999.
The present invention concerns connection management communications system, especially in a mobile communications system suitable for packet switched data transmission.
Telecommunication networks can be divided into circuit switched and packet switched networks. In circuit switched networks, the transmission connection between the transmitting party and the receiving party is reserved before starting the transmission. It is a drawback of this connection method that the transmission connection is reserved even if no information is transmitted over the connection. In packet switched networks, transmission of packets may be connection-oriented or connectionless. In connectionless packet switched networks, the transmission network is common to all users. Information is transmitted in packets which contain information on their destination. Resources of the transmission network are not reserved in advance, nor are any packets transmitted when there is no information to be transmitted. In this way no transmission network capacity is reserved unnecessarily. In the connection-oriented packet switched technology, virtual circuits are formed for certain transmission routes between network elements and every packet of the connection is routed along the same route. Thus, the information is routed as in circuit switched networks, but no transmission capacity is unnecessarily reserved. E.g. the ATM (Asynchronous Transfer Mode) network is formed with the aid of virtual circuits.
Accessing packet switched networks like the Internet is further possible in many ways. The pan-European GSM mobile communications system, which is based on time division multiple access TDMA, allows circuit switched connection to packet switched networks in a known manner, when an adaptation protocol (e.g. a point-to-point protocol, PPP) is used between the mobile station and the connection point located in the network. The GPRS service (General Packet Radio Service) defined in the GSM system also allows packet switched connection from mobile stations to packet data networks like the Internet.
In the GPRS network, transmission of packets between the mobile station and the serving node is transparent from the viewpoint of the base station system, and no record relating to the mobile station's GPRS service is stored in the base station system. Instead, every serving node SGSN has context information about the mobile stations which it is serving. In the GPRS system, context information can be divided into mobility management MM and packet data protocol PDP information respectively. The mobility management will tell where the mobile station is located and in which state it is. Possible states of a mobile station registered with a GPRS system are the idle state, the standby state and the ready state. When in the idle state, the mobile station is passive and it is able to receive only the broadcast of the base stations, but no point-to-point packets can be transmitted between the mobile station and the network. In the ready state, the mobile station is able to receive packets without any call procedure. From the ready state the mobile station moves to the standby state after a certain non-activity period. From the standby state the mobile station returns to the ready state after a call from the network or for transmission of a packet. The move between idle state and active state takes place by GPRS Attach and GPRS Detach procedures. In the ready state, the network knows the location of the mobile station with one-cell precision. Each packet to the mobile station is routed individually with the aid of a cell identifier attached to the packet from the serving node to the correct base station. Thus, user information is transmitted between the network and the mobile station without any connection assigned between the base station system and the serving node SGSN.
In the third generation mobile communications system, the radio network subsystem must have information about mobile stations to be served over the radio interface, because the radio network subsystem allocates radio resources for the subscribers and it is able to combine both circuit switched and packet switched connections of the mobile station in the radio interface, using the same spreading code when e.g. WCDMA technology is used. It has been proposed that connections over the Iu interface between the radio network and the main trunk should be connection-oriented due to the said combining and coding of circuit switched and packet switched traffic. In addition, a connection set-up to be made for the packet service allows advantageous transmission to the radio network subsystem of parameters describing the quality of the service (e.g. transmission rate, transmission delay). Without a connection set-up which takes place separately, these parameters must be added separately to each packet to be transmitted. A connection between the serving node and the radio network subsystem can be implemented e.g. with ATM in such a way that for each mobile station a virtual channel is reserved according to a certain ATM adaptation layer (e.g. ATM Adaptation Layer 5 AAL5 or ATM Adaptation Layer 2 AAL2).
In order to combine circuit switched and packet switched traffic in a radio network subsystem, it is preferable to unify the mobile station state management. For this reason, an idle state and an active state are proposed as mobility management (MM) states of the mobile station registered with the 3G network. These states differing from the GPRS system are also natural states, when the transmission of packet data between the serving node and the radio network is connection-oriented, as presented above. In the idle state, the mobile station is only able to listen to the broadcast of base stations and to move into an active state through a procedure to be described later in connection with
In the operation of the third generation mobile communications system it is a problem as regards the transmission of packet data that resources of the transmission path between serving node SGSN and the radio network subsystem as well as memory resources of the radio network subsystem are reserved unnecessarily due to the burst-like character of packet data. Since a connection can be set up e.g. in the morning and end only in the evening, an address is reserved on the transmission path and connection management resources are reserved in the radio network subsystem for the whole day, even if no packets to be transmitted were to travel in the virtual circuit. Thus, a connection-oriented connection as described above for the serving node and the radio network subsystem consumes the transmission network's limited address space and the radio network subsystem's management resources.
The objective of this invention is to save limited address space of the transmission network and to save management resources of an access system.
This objective is achieved by a method and a communications system in accordance with the invention, which are characterized by that which is said in the independent claims. Advantageous embodiments of the invention are presented in the dependent claims.
The invention is based on the idea that the logical communication connection between the access network and the serving node of the trunk network is released while the data transmission is inoperative, and this communication connection is again set up, when transmission of user data begins. The communication connection between the access network and the serving node is released in such a way that the logical connection between the serving node and the terminal will remain. If said communication connection between the serving node and the access network was the terminal's last connection, the terminal will enter a 3 G idle state in accordance with the invention, which corresponds to the idle state of circuit switched services. While the communication connection is released in accordance with the invention, the terminal keeps the packet data address, whereby a packet data transmission can be started to and from the terminal. When the packet data transmission begins, a communication connection is again set up between the access network and the serving node. In a first embodiment of the invention, the communication connection is released when the inactivity of data transmission has lasted for a predetermined period of time.
It is an advantage of this kind of connection management that the limited address space of the transmission network is saved, when the addresses of inactive connections are freed for other use, and the management resources of the access system are saved.
The invention will now be described in connection with advantageous embodiments and referring to the examples shown in
The present invention can be applied in connection with any suitable communications system. Hereinafter the invention is described more closely by way of example mainly in connection with a digital 3G mobile communications system with the focus on that part of the system which is intended for packet data transmission.
In the following, the invention will be described in greater detail in the light of a first embodiment of the invention.
In the first embodiment of the invention, the timer and the trigger value can be set e.g. in such a way that disconnection of the connection is started after a ten-minute idleness period. The idleness period starting disconnection of the connection according to the invention can be set individually for the different connections, e.g. at some value between 1 and 10 minutes. In addition, the control of the timer's setting value may also depend on the subscribed service class. The timer may be located on the network side, preferably in connection with the serving node SGSN, or/and on the mobile station side. In the PDP Context activation procedure at stage 32 in
In the second embodiment of the invention, disconnection of the connection between the radio network subsystem and the serving node SGSN is triggered off by a shortness of resources at the Iu interface. In the second embodiment of the invention, traffic monitoring is performed in the network in the same way as was described above in connection with the first embodiment of the invention.
In a first manner of implementation of the third embodiment of the invention, the radio network subsystem RNS can prevent disconnection of a connection over the Iu interface. Such a functionality may be needed e.g. in a situation where a mobile station has transmitted to the radio network a data packet, which the radio network subsystem has received, but of the relaying of which the serving node does not yet know. When the SM protocol starts releasing resources of the Iu connection in accordance with the invention by the Release procedure 57 of
In a second manner of implementation of the third embodiment of the invention, MS does not accept a change of the MM mobility management state to the active state as commanded by the serving node SGSN. Such a functionality may be needed e.g. in a situation where a mobile station has transmitted a data packet, of the switching of which the serving node, however, does not yet know. Hereby the SM protocol will not start any release of resources of the Iu connection.
In a third manner of implementation of the third embodiment of the invention, the serving node SGSN does not accept the change of the MM mobility management state to an idle state from an active state as commanded by the mobile station MS. Such a functionality may be needed e.g. in a situation, where the serving node has transmitted a data packet, of the switching of which the mobile station, however, does not yet know. Hereby the SM protocol will not start any release of the resources of the Iu connection.
The drawings and the relating explanation and the names of procedures occurring therein are only intended to illustrate the inventive idea. As regards its details the connection management according to the invention may vary within the scope defined by the claims. Although the invention was described above mainly in connection with a 3G mobile system implemented with WCDMA technology, the invention may also be used for some other kind of mobile system, e.g. for a system implemented with TD-CDMA technology. The invention is also suitable for use with the type of connectionless connection existing between a trunk network and a radio network, e.g. in a Frame Relay case. The radio network mentioned in this application may be e.g. UTRAN (UMTS Terrestrial Radio Access Network).
Ahmavaara, Kalle, Verkama, Markku, Hartikainen, Jari, Perala, Timo
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