RU2300847C2 - Mobile distant radio communication method and network for burst data transfer - Google Patents

Abstract

FIELD: controlling data exchange between mobile subscribers in burst-oriented mobile communication network.

SUBSTANCE: proposed method is characterized in that each subscriber is serviced depending on his actual location in mobile communication system at definite Serving GPRS Support Node (SGSN) of the latter; mobile-subscriber communication terminal-to-terminal connections within mobile communication network are controlled by respective network control node so that address register with all addresses assigned to mobile subscribers serviced by network control node is stored in network control node; target address assigned to data bursts is read out of arriving burst data in network control node and compared by means of search function with address register; if address register holds target address, data bursts are processed within mobile communication network and further transferred by means of network control node only; in absence of target address in address register, data bursts are passed from network control node to other node (GGSN) of mobile communication network.

EFFECT: optimized routing of burst data.

9 cl, 1 dwg

Description

The invention relates to a method for a mobile remote radio communication network for transmitting packet data between two mobile communication terminals. In networks for mobile communications, there are many network elements that are involved in the transmission of voice data, multimedia data or other useful data. The modern architecture of mobile radio networks suitable for transmitting packet data, such as, for example, in GPRS and / or UMTS networks, differs among other things in that there is a central transition point in the case of a GPRS network, for example, the so-called GGSN, which provides binding to the packet network data, such as to the Internet. Between the mobile communication terminal and the central transition point, subscriber data is tunneled to support the mobility of the mobile communication terminal. A specific spatial area, the so-called Routing Area, is assigned exactly one network control node, in the case of a GPRS network, the so-called SGSN, which controls the mobility of a mobile communication terminal. Regarding the construction and maintenance of logical connections, such as PDP contexts, networks are optimized for the so-called client-server services. With this type of communication, in principle, many subscribers or, accordingly, clients communicate from any place, for example, in the form of a star with a central server coordinated with the incoming load. Another feature is the highly asymmetric traffic characteristic. There is too little message flow from the subscriber or, accordingly, the client to the server, on the contrary, a relatively large message flow from the server to the subscriber. The usual scenario is, for example, a data flow between a mobile communication terminal and a target that lies outside the actual mobile remote radio communication network, that is, behind a central transition point, such as, for example, a host on the Internet or WAP-GM.

According to this, mobile radio communication networks are not suitable for applications that send data from one mobile communication terminal to another mobile communication terminal. Such direct data transfers from one user to another user are referred to as peer-to-peer or, respectively, as P2P transmission. At present, in particular, on the Internet, however, an over-proportional increase in the flow of data has been identified precisely with the so-called P2P services. A striking example is, for example, exchange exchanges for music and video clips, which are based on direct exchange of data between users.

With the increasing scope of functions of mobile communication terminals, such as digital cameras, MP3 players or multimedia cards, also among mobile users or, accordingly, in the case of so-called mobile subscribers, one should expect similar user behavior. In contrast to simple text messages and ringing tones, which can be sent well through the so-called Short Message Service, i.e. SMS, the data flow caused by the transfer of, for example, audio files or still image files or data streams will grow exponentially. From the point of view of the network operator, it will thus become more and more attractive in the course of time in such a scenario to route data directly, if possible, and thereby save costs.

Thus, the object of the present invention is to better support the so-called peer-to-peer P2P services in mobile radio networks, in particular in GPRS or, accordingly, UMTS networks, and optimize packet data routing in especially common situations.

This problem is solved by the method according to paragraph 1 of the claims and the mobile radio network according to paragraph 4 of the claims. Further preferred forms of implementation are given in the dependent claims.

According to paragraph 1 of the claims, a method is provided for controlling data exchange between mobile subscribers in a packet-oriented mobile radio communication network, wherein

- each subscriber, depending on his respective location in the mobile radio communication network, is served in a specific control node of the network (SGSN) of the mobile radio communication network,

- connections from the mobile terminal / to the mobile communication terminal of the mobile subscriber within the mobile radio communication network are controlled by the corresponding control node of the network,

at which

- in the control node of the network remember the address register with all addresses assigned to mobile subscribers served by the control node of the network,

- in the control node of the network from the incoming data packets, the target address assigned to the data packets is read and, by means of the search function, compared with the address register,

- if there is a target address in the address register, data packets within the mobile radio communication network are processed and sent further exclusively through the control node of the network,

- in the absence of a target address in the address register, data packets are transmitted from the control node of the network for further processing to another network node (GGSN) of the mobile radio communication network.

As already mentioned, it is known that the subscriber data packets that pass through the mobile radio network transparently, that is, tunneled, become visible only after the central transition point, in the case of a GPRS network, for example, after the GGSN, that is, after the end tunnel point. Based on this central transition point, the data packets are then transported by conventional routing to the corresponding destination address. The first mobile communication terminal, for example, a data packet is tunneled through a control unit, in the case of a UMTS network, for example, via a Radio Network Controller (RNC), a network control node, such as, for example, SGSN to a central transition point, such as GGSN. At the central transition point, then the incoming data packet is disbanded or, respectively, decapsulated and then routed. If in the case of the destination address we are talking about another second mobile communication terminal, then the data packet is routed to the central communication node that serves the tunnel to the second mobile communication terminal. There, the data packet is again packetized or, respectively, encapsulated and finally tunneled through the control node of the network, such as SGSN and the control unit, such as the remote network controller Radio Network Controller (RNC) to the target address, i.e. to the second mobile communication terminal.

The exchange of multimedia content between two mobile communication terminals could still take place, for example, through the so-called multimedia message service Multimedia Message Service (MMS). In the case of this service, there is the so-called Multimedia Message Service Center (MMSC), which serves when applying the so-called principle of intermediate storage as intermediate memory. In this service, data packets to be forwarded from one mobile communication terminal to another mobile communication terminal, in general, through spatially far remote network nodes, even if the mobile communication terminals lie in place close to each other. The consequences are unnecessarily high latent latency times, as well as unnecessary network load, where additional data packets might otherwise be transported.

An advantage of the present invention is now that the routing of these data packets is optimized if the mobile communication terminals exchanging data lie locally close to each other and therefore are served by the same control network node, in the case of a GPRS network, for example, the same SGSN. Due to the search functions provided by the invention in the control node of the network, relevant data packets are recognized and bypassing the further node of the network, as in the case of a GPRS network, for example, a GGSN, is processed exclusively by the control node of the network, such as, for example, SGSN. A noticeable share of the data flow between two mobile communication terminals is caused by users who are spatially located near each other, such as when exchanging ringing sound signals, logos or MP3 data between friends or acquaintances. According to the invention, in these cases, the data flow in the so-called backbone of a mobile radio communication network, such as, for example, in a GPRS backbone between SGSN and GGSN, is greatly reduced. Always, if the data packet is provided with a target address, which is set aside in the address register of the control node of the network, this is recognized by the search function according to the invention and thus recognized as a relevant data packet according to the invention is still processed and passed on to the control node of the network. Bypassing through other network nodes is thereby avoided according to the invention. If the target address is not in the address register, then the data packet is transmitted from the control node of the network to the next network node, as, for example, to the GGSN in the GPRS network, which manifests itself responsible for sending the data packet to its target address.

In a particularly preferred embodiment of the method according to the invention, the so-called hash table with a hash function is selected as the address register in order to be able to quickly decide whether an incoming IP packet should be transmitted further locally or via GGSN. The hash table consists of a list of entries that contain only the binary value "1" or "0". The classification criterion, that is, the addresses in the table, is calculated directly by means of a hash function. This happens by converting the IP address to its 32-bit or, accordingly, 128-bit value, with which you can directly access the table. If the test with the destination address of the IP packet arriving at the SGSN gives, for example, the value "1", then this signals the presence of a local target, that is, the communication partner is registered on the same SGSN as the sender of the IP packet, and then the further transmission of the IP packet according to The invention handles exclusively SGSN. If the test gives a value of "0", then the IP packet should be routed through the GGSN. The table is updated during PDP context processing. For this, at each formation or, accordingly, reduction or modification of the context, the IP address of the corresponding subscriber in the table is set to the corresponding value, that is, for example, to “1” for “locally” and “0” for “not available”.

Preferably, a GPRS or UMTS network is selected as the mobile radio communication network.

In addition, the present invention encompasses a mobile radio communication network with at least one control network node, in which mobile subscribers of the mobile radio communication network are served depending on their current location and connection from the terminal / to the communication terminal of the mobile subscriber served in the control network node, inside the mobile radio communication network, moreover, a filtering function is provided in the control node of the network, with the help of which incoming data packets are filtered out depending on the corresponding Twain of the data packet's destination address.

Preferably, a table is provided in the control node of the network in which all subscribers served by the control node of the network are listed with the corresponding addresses assigned to the subscribers. Using this table, it is preferable by means of the filtering function to compare the target address specified in the data packet with the addresses respectively assigned to subscribers in the table.

In a particularly preferred embodiment of the mobile radio communication network according to the invention, a routing function is provided in the control node of the network by which selected data packets with a target address can be routed to this target address bypassing other network nodes.

In a particularly preferred embodiment of the mobile radio communication network according to the invention, in the control node of the network, the filtering function and the routing function are interconnected in such a way that the data packets filtered by the filtering function depending on the target address specified in the data packets can be transmitted further bypassing other hosts using the routing function to the corresponding destination address. This means that if the target address of the data packet arriving at the control node of the network is in the address register of the control node of the network and this is recognized by the filter function of the control node of the network, then this data packet is routed directly bypassing other nodes by means of the routing function provided in the control node of the network networks, such as the GGSN in the GPRS network, to the destination address. This can save time and costs.

According to the invention, thereby the so-called Peer-to-Peer services of the same level or, accordingly, P2P services are supported by analogy with developments on the Internet also in a mobile radio communication network. By means of the invention, both the operator and the mobile subscriber, which are served by the same control node of the network, can benefit from geographical proximity. For the operator, a lower network load between the SGSN and GGSN is obtained, for the mobile subscriber there are less latent times and therefore lower tariffs.

Further advantages are explained on the basis of the drawing, which shows a schematic representation of a form of execution corresponding to the invention of the method on the example of a GPRS network.

The drawing shows a form of execution corresponding to the invention of the method on the example of a GPRS network. In the present example, a remote network controller Radio Network Controller RNC-A is presented from the GPRS network, which is responsible for accessing the network of mobile subscriber A with its mobile communication terminal MS A, the control node SGSN, which, due to its spatial proximity, serves as mobile subscriber A c by its mobile terminal MS A, as well as another mobile subscriber B located nearby with its mobile terminal MS B, GGSN, which in the present case for both A and B serves as a central transition point for binding to the packet data network, referred to in the standards as the logical reference point Gi, and the second remote network controller Radio Network Controller RNC-B, which is responsible for accessing the network of mobile subscriber B. Now, mobile subscriber A would like to use his mobile communication terminal MS A make a connection to the mobile subscriber B or, respectively, to his mobile communication terminal MS B and transmit data packets over it. Outgoing from the subscriber A or, respectively, its terminal MS A, the data packet contains the target address, namely, in the case presented, the address of the subscriber B or, accordingly, its MS B. It is known that the dashed line shows that the data packet is from MS A tunnel through the remote network controller Radio Network Controller RNC-A, SGSN to GGSN. In RNC-A, a data packet is encapsulated in an appropriate IP tunnel. This means that the data packet is processed transparently up to the GGSN. Upon logical consideration, the data packet is disbanded, that is, only after GGSN is decapsulated, namely, at the reference point Gi and from there, using the destination address delayed in the data packet, they route or, accordingly, direct it to this target address. This means in the present case, when the target destination, namely, subscriber B, is located in the vicinity of subscriber A, that based on the reference point Gi, the data packet is now sent back to the same GGSN, there it is again formed into a packet, that is, encapsulated and from there to the same SGSN, which serves both subscriber A and B. From SGSN, then the data packet is sent to RNC-B and, finally, to MS B. The section between SGSN and GGSN, as well as between GGSN and, for example, external the router, which is connected at the Gi reference point, travels twice, which is not zhnym for the desired process, namely the sending of a data packet from A to B. The SGSN according to the invention now has the address table, a search function and a routing function. In the table, each subscriber served by SGSN is assigned an IP address assigned to him during the creation of the PDP context. The table is designed in such a way that by means of the search function and the destination address, which is deferred in the incoming data packet, it is possible to very quickly determine whether the destination address is contained in the table or not. If the destination address of subscriber B is contained in the table, as is the case in the present example, the search function reads the interface identification, which indicates the physical connection of the RNC-B network controller serving subscriber B, and a data packet is sent directly through this interface to RNC-B. By processing data packets on the interface to the radio access network, the GGSN is bypassed. Thus, the function of evaluating the target addresses of the search or, respectively, filtering of the SGSN node in conjunction with the address register or, accordingly, the table of all SGSN subscribers or their IP addresses serviced by the corresponding moment of time, allows optimized routing for data packets to be sent between all subscribers served at the appropriate time by this SGSN.

Claims (9)

1. A method for managing data exchange between mobile subscribers (A, B) in a packet-oriented mobile communication network, in which each subscriber (A, B) is served in a specific control network node (SGSN) depending on its current location in the mobile communication network mobile communication networks, and connections from the mobile terminal and to the mobile communication terminal of the mobile subscriber (A, B) within the mobile communication network are controlled using the corresponding control network node (SGSN), namely, in the control network the node (SGSN) stores the address register with all the addresses assigned to the mobile subscribers (A, B) served by the control network node (SGSN), the target address assigned to the data packets is read from the incoming data packets in the control network node (SGSN) and, using the search function, compare with an address register, if there is a target address in the address register, data packets within the mobile network are processed and transmitted further exclusively through the control network node (SGSN), in the absence of a target address in the address reg in the past, data packets are forwarded from the control network node (SGSN) for further processing to another network node (GGSN) of the mobile communication network. 2. The method according to claim 1, characterized in that a hash table with a hash function is selected as the address register. 3. The method according to claim 1 or 2, characterized in that the GPRS or UMTS network is selected as the mobile communication network. 4. A mobile radio communication network with at least one control network node (SGSN), in which the mobile subscribers (A, B) of the mobile radio communication network are served depending on their current location, and the connection from the terminal to the communication terminal of the mobile subscriber ( A, B), served in the control network node (SGSN), are managed within the mobile radio network, characterized in that the control network node (SGSN) has a filtering function, with which the incoming data packets are filtered out depending on the destination address specified in the data packets. 5. The mobile radio communication network according to claim 4, characterized in that in the control network node (SGSN) a table is provided in which all subscribers (A, B) served by the control network node (SGSN) with the corresponding addresses assigned to the subscribers are entered. 6. The mobile radio communication network according to claim 5, characterized in that the filtering function compares the target address specified in the data packet with the addresses in the table correspondingly assigned to the subscribers. 7. A mobile radio communication network according to any one of claims 4 to 6, characterized in that a routing function is provided in the control network node (SGSN) by which selected data packets with a destination address can be routed to that target address bypassing other network nodes. 8. The mobile radio communication network according to claim 7, characterized in that in the control network node (SGSN) the filtering function and the routing function are interconnected in such a way that the data packets filtered by the filtering function, depending on the target address specified in the data packets, transmit Further, using the routing function bypassing other network nodes to the corresponding destination address. 9. The mobile radio communication network according to any one of claims 4 to 6, characterized in that in the control network node (SGSN) the filtering function and the routing function are interconnected in such a way that they are filtered using the filtering function depending on the target data packet The data packets are transmitted further using the routing function, bypassing other network nodes to the corresponding destination address.