DE10017062B4 - Method for operating a mobile radio network - Google Patents

Abstract

Method for operating a mobile radio network (1), in which user data is transmitted between a mobile station (10) and a first base station (25), the user data being assembled into data units prior to their transmission, wherein for the transmission of the data units both in the mobile station ( 10) as well as transmission-specific information describing a current state of the transmission to be stored in a first network unit (50) superordinate to the first base station (25), that upon a connection change of the mobile station (10) from the first base station (25) to one second base station (30) with a second higher-level network unit (55) transmit the transmission-specific information stored in the first higher-level network unit (50) to the second higher-level network unit (55) in order to continue the transmission after the connection change directly from its current state, characterized gekennzeic hnet that prior to or at the connection change a signaling information from the first parent network unit (50) to the mobile station (10) is transmitted to the mobile station (10) to communicate whether the transmission-specific information in this connection change to the second parent network unit (55) should be.

Description

State of the art

The invention is based on a method for operating a mobile radio network according to the preamble of the main claim.

In the post-published German patent application with the file number DE 199 44 334 C1 A method for operating a mobile radio network is already shown, in which user data are transmitted between a mobile station and a first base station, the user data being assembled before their transmission into data units, in particular packet data units.

From the 3GPP TS 25.413 V1.3.1 (1999-09) a method is known in which a signaling protocol of "Radio Network Layer" for the interface Iu is specified. This signaling protocol is called the "Radio Access Network Application Part". For a successful connection switch in a PS (Packet Switched) domain, a "RELOCATION REQUIRED" message is sent from the source RNC (Radio Network Controller) to the core network. Thereafter, the core network transmits a message "RELOCATION COMMAND" to the source RNC, and the message "RELOCATION COMMAND" may include the information "Destination RNC compliant Iu transport address" and "Iu transport association".

In TSG-R3 (99) c60, TSG-RAN WG3 meeting, Sophia Antipolis, France, (September 20-24, 1999) a proposal is disclosed in which a lossless relocation is supported. In this case, a timer is upgraded and the transmission of the downlink data from the source RNC to the destination RNC via the interface I _u started.

The ETSI standard EN 301 344 V6.3.2 (1999-07) discloses a combined RA / LA update (Routing Area / Location Acknowledgment Update) in the case of the Inter SGSN RA update procedure. In response to the "SGSN Context Request" message, the old SGSN sends a "SGSN Context Response" message to the new SGSN with the content of MM (Mobility Management) Context, PDP (Packet Data Protocol) Contexts and LLC Ack (Logical Link Control Acknowledgment). The old SGSN starts a timer and stops the downlink transmission. Further, the old SGSN duplicates the stored N-PDUs as well as the additional N-PDUs received from the GGSN (Gateway GPRS Support Node) and, before the expiration of the timer, starts tunneling these N-PDUs to the new SGSN.

From the WO 99/41850 A2 For example, there is known a method dedicated to the control activities in a situation where a mobile terminal is simultaneously in radio communication with at least two base stations. In particular, the method is dedicated to the transmission of call control related parameters between the mobile system parts which are important in data transmission, for instance between the RNCs as well as between the RNC and the base station.

The EP 0 898 438 A2 discloses a method which addresses the problem of handover in a new mobile radio system comprising a "Core Network" and a new type of "Generic Radio Access Network (GRAN)" as well as a mobile terminal, the "Core Network" among others has a "Mobile Services Switching Center (MSC)" and several "Radio Network Controllers (RNCs)" with their associated base stations (BSs) are connected to the MSC.

There are 3 categories of handover: 1) Handover between base stations, ie. H. Intra-RNC handover; 2) Handover between "Radio Network Controllers" within a GRAN, d. H. Inter-RNC handover; and 3) handover between GRANs, d. H. Inter-GRAN handover. In the Inter-RNC Handover, a physical link is provided between the two "Radio Network Controllers". This allows the handover signaling to be transferred directly from one "Radio Network Controller" to the other without involving the "Core Network CN".

From the WO 99/22557 A2 For example, a method is known in which data is assembled in units through a first convergence protocol layer (SNDCP) before being transferred to a peer convergence protocol layer (SNDCP). In this case, at least one Access Point Identifier (NSAPI) is assigned to each user and one or more set up messages (XID) are exchanged between the first and second convergence protocol layers, each message including a data compression algorithm identifier / decompression algorithm identifier. The method further includes a set of the parameters for the identified algorithm and a bitmap of the access point identifier.

Advantages of the invention

The inventive method with the features of the main claim has the advantage that for the transmission of the data units in both the mobile station and in the first base station parent first network unit transmission-specific information, the Describe a current state of the transmission to be stored, that in a connection change of the mobile station from the first base station to a second base station with a second parent network unit, the stored in the first parent network unit transfer-specific information is transmitted to the second parent network unit to the transfer to to continue the connection switch substantially directly from its current state. In this way, a continuous transmission of the data units is possible regardless of the connection change. Resetting the transmission-specific information to an initial state is thus not required when connecting. The radio transmission between the mobile station and the second base station after the connection change is thus not affected by the transmission of data in its transmission capacity, which are required for a restoration of the last valid transmission-specific information in the second higher-level network unit.

The measures listed in the dependent claims advantageous refinements and improvements of the main claim method are possible.

It is particularly advantageous that control information is added to the data units before their transmission, that the control information is compressed by means of differential coding prior to their transmission, wherein a codebook is applied for the coding and decoding of the control information in the mobile station and in the first higher-level network unit wherein the two applied codebooks have an identical content, and that the transmission-specific information at the connection change, the codebook stored in the first higher-level network unit is transmitted to the second higher-level network unit. In this way, the second higher-level network unit can take over the codebook created during the transfer of the data units between the mobile station and the first base station in the mobile station and the first higher-level network unit directly from the first higher-level network unit during the connection switch, so that the codebook does not reappear after the connection is switched must be applied or set up under load of the transmission capacity for the transmission between the mobile station and the second base station.

A further advantage is that, before or during a connection setup for the transmission of the data units between the mobile station and the first base station, a first signaling information is transmitted from the mobile station to the first higher-level network unit in order to notify the first higher-level network unit if a connection changes to one Base station with a different from the first parent network unit new parent network unit to transmit the transmission-specific information to the new parent network unit. Another possibility is to transmit this first signaling information from the first superordinate network unit to the mobile station, so that the network can decide whether the transmission-specific information is to be transmitted from the first superordinate network unit to the new superordinate network unit. This is particularly advantageous because the first parent network entity has knowledge of the capabilities and resources of the new parent network entity and the landline over which the transmission-specific information must be transmitted. In any case, a choice is given in this way, depending on the need to provide a transfer of the transmission-specific information from the first parent network unit to the new parent network unit for a telecommunications connection to be established at a connection change. In addition, in this way it is possible for the connection to be established to reset the transmission-specific information to an initial state after the connection change. The method according to the invention can therefore be used flexibly.

Another advantage is that prior to or at the connection change a second signaling information from the mobile station to the first parent network unit or from the first parent network unit to the mobile station is transmitted to the first parent network unit or the mobile station to tell whether in this connection change the transmission-specific information to the second parent network unit to be transmitted. In this way, it is also possible to provide transmission of the transmission-specific information from the first higher-level network unit to the second higher-level network unit for a telecommunication connection to be established or a reset of the transmission-specific information to an initial state during a connection change during a connection as required, so that the method according to the invention is particularly is flexible.

Another advantage is that with the transmission-specific information at the connection change in the first higher-level network unit for control purposes cached data units are transmitted to the second parent network unit. In this way, for the control of the transmission of the data units, in particular for error-free transmission, cached data units which are required and possibly repeatedly to be transmitted are not lost during the connection change.

It is also advantageous that the transmission-specific information is transmitted during the connection change over a landline between the first parent network unit and the second parent network unit. In this way, the generally higher data rate of the fixed network can be used to transmit the transmission-specific information, without claiming the transmission capacity of the mobile network for this transmission.

drawing

An embodiment of the invention is illustrated in the drawing and explained in more detail in the following description. Show it 1 a block diagram of a mobile network, 2 a block diagram for a connection between a mobile station and a first higher-level network unit via a first base station before a connection change, 3 a block diagram for a connection between the mobile station and a second superordinate network unit via a second base station after a connection change, 4a) a compression table and 4b) a buffer for data units.

Description of the embodiment

The invention deals with a method for operating a mobile radio network 1 according to 1 in which, during an established connection, a connection change between two base stations 25 . 30 which is also called "relocation". The mobile network 1 can be constructed, for example, according to the GSM standard (Global System for Mobile Communications) or according to the UMTS standard (Universal Mobile Telecommunications System). Specifically, the method relates to the transmission of transmission-specific information of the established connection, for example in the form of internal protocol information of a convergence protocol layer 130 . 135 , between two parent network entities 50 . 55 the cellular trained mobile network 1 ,

The cellular mobile network 1 consists of different units 10 . 20 . 25 . 30 . 35 . 50 . 55 . 60 that are physically connected to each other. It indicates 10 a mobile station of the mobile network 1 , which may be formed for example as a mobile telecommunication terminal. The mobile telecommunication terminal 10 is via a first air interface 90 with a first base station 25 the mobile network 1 connected. The first base station 25 is over a first landline connection 81 with a first parent network entity 50 connected. A second base station 30 is via a second landline connection 82 with a second parent network entity 55 connected. A third base station 20 is via a third landline connection 80 with the first parent network entity 50 connected. A fourth base station 35 is over a fourth landline connection 83 with the second parent network entity 55 connected. The first parent network unit 50 is via a fifth landline connection 85 with a highest network unit 60 connected. The second parent network unit 55 is over a sixth landline connection 86 with the highest network unit 60 connected. Optionally, the first parent network entity 50 via a seventh landline connection to the second parent network entity 55 be connected as in 1 is shown in dashed lines. The first parent network unit 50 , the second parent network entity 55 and optionally other higher-level network units form according to the UMTS standard so-called "Radio Network Subsystems" (RNS). According to the UMTS standard, the highest network unit forms a so-called "GPRS Support Node" (GSN).

In the cellular mobile network 1 become for data transmission between the mobile telecommunication terminal 10 and the other units of the mobile network involved in the established connection 1 made logical connections. There are different types of logical connections between the mobile telecommunication terminal 10 and the various units involved in the mobile network 1 simultaneously. These logical connections originate from a hierarchical model in which each hierarchical layer corresponds to a protocol used in both the mobile telecommunication terminal 10 as well as in the appropriate unit of the mobile network 1 is present and that realizes the corresponding logical connection.

According to 2 are exemplary the logical connections between the mobile station 10 and the first parent network entity 50 as well as between the mobile station 10 and the first base station 25 shown. The lowest hierarchical layer in this hierarchical model is through a first physical layer 110 in the mobile telecommunication terminal 10 and a second physical layer 115 in the first base station 25 formed, which is one of the first air interface 90 corresponding physical connection between the mobile telecommunication terminal 10 and the first base station 25 the mobile network 1 realize. In addition there is a data protection layer, which according to the UMTS standard is also referred to as "data link layer", which is divided into several sub-layers and different logical connections between the mobile telecommunication terminal 10 and the first higher-level network entity referred to as the "Radio Network Controler" (RNC) according to the UMTS standard 50 realized. One such sublayer, in accordance with the UMTS standard, is the radio link control layer, also referred to as the "Radio Link Control" (RLC) layer, in which a first RLC protocol 120 in the mobile telecommunication terminal 10 and a second RLC protocol 125 in the first parent network unit 50 a first logical RLC connection 101 as one of the mentioned logical connections. Another sublayer is the packet data convergence protocol layer, which is also referred to as the Packet Data Convergence Protocol (PDCP) layer in accordance with the UMTS standard, and in which a first PDCP protocol 130 in the mobile telecommunication terminal 10 and a second PDCP protocol 135 in the first parent network unit 55 a first logical PDCP connection 102 realize. In the higher hierarchical layers, such as the network and transport layer, other protocols such as the Radio Resource Control RRC, the Internet Protocol IP, the Transit Control Protocol (TCP), and the like can establish other logical connections. According to 2 In the hierarchical model, adjacent layers are interconnected, with higher layers occupying the services of the corresponding adjacent subordinate layers. The second physical layer 115 is like in 1 indicated via the first fixed network connection with the first higher-level network unit 50 and there with the second RLC protocol 125 connected.

From the publication "Technical Specification 25.301, UMTS Radio Interface Protocol Architecture" the corresponding UMTS protocol architecture of the so-called layers 2 and 3 is known, which also includes the packet data convergence protocol layer. In particular, the packet data convergence protocol layer and its location within this architecture is known. The PDCP protocol 130 . 135 is known from the publication "Technical Specification 25.323, Packet Data Convergence Protocol", insofar as it has been specified so far.

A task of the PDCP protocol 130 . 135 is the compression of packet data control information added by the protocols of the transport and network layer above the packet data convergence protocol layer to the payload data also aggregated in the packet data protocol layer before transferring it to data units or packet data units to an application also running above the packet data convergence protocol layer; before transmission over the first air interface 90 must be compressed to allow efficient transmission.

The compression is possible in different ways. Compression algorithms are specified, for example, in the publication IETF, RFC 1144 or in the publication IETF, RFC 2507. The most efficient compression algorithms make use of the fact that the packet data control information in successive packet data units of a particular data type does not differ or only to a certain extent. A differential encoding is applied to the packet data control information, which uncompresses the packet data control information of the first packet data unit of a first data type or other reference packet data and transmits the difference to the previous packet data control information or to the other reference packet data control information for all other packet data units of this data type , The data types of the packet data units can be given, for example, by the used transport and network layer protocols. For example, a first data type can be specified by a TCP / IP protocol and a second data type by a UDP / IP protocol (User Datagram Protocol).

In order to enable efficient compression of the packet data control information, even if a packet data stream consists of packet data units of different data types, a table is created during the encoding on the receiver and transmitter side into which the packet data control information of the various data types is stored. For each packet data unit to be compressed, it is first checked in the table whether a similar or identical entry has already been stored there. If so, then the difference coding between the new and in-table packet data control information is executed and the decompressor on the receiver side not only transmits the difference but also signals the table entry to which the difference coding was applied. If no matching entry is found in the table on the sender side, then the packet data unit is understood as a new data type. In addition, the associated packet data control information is added as a new entry in the table and transmitted uncompressed. The recipient also includes this package in his table.

For efficient compression of packet data control information of packet data streams, during compression on the sender and receiver side, tables, also referred to as compression tables or codebooks, are created. These codebooks make the difference coding described possible. In order to be able to decode such differential-coded packet data control information, the tables on the sender and receiver sides must always match.

The cellular mobile network offers the possibility of data transmission from the mobile telecommunication terminal 10 to a unit of the mobile network 1 even if the user of the mobile telecommunication terminal 10 from the first base station 25 spanned radio cell leaves. This is between the mobile telecommunication terminal 10 and the mobile network 1 a method for transferring the established connection for data transmission from the first base station 25 to the second base station 30 provided the user of the mobile telecommunication terminal 10 moves into from the second base station 30 spanned radio cell. This connection change is also described as "relocation" as described.

When a connection change, it may now be that the second base station 30 to which the connection is to be transferred is connected to a different superordinate network unit than the previous first base station 25 , This is the case in the described embodiment, according to which the second base station 30 unlike the first base station 25 with the second parent network entity 55 connected is.

Each protocol always exists at least twice at the same protocol layer level in different network entities, as well as in 2 the RLC protocol and the PDCP protocol both in the mobile telecommunication terminal 10 as well as in the first parent network unit 50 exist. Especially the PDCP protocols 130 . 135 lie according to the UMTS standard as described on the one hand in the mobile telecommunication terminal 10 and second, in the first parent network entity 50 as well as in other higher-level network units, which are designed as RNC. In the case of the described connection change, the existing data connection between the mobile telecommunication terminal 10 and the mobile network 1 so laid that over the second base station 30 and the second parent network entity 55 runs. This sends the first PDCP protocol 130 in the mobile telecommunication terminal 10 before switching to the second PDCP protocol 135 in the first parent network unit 55 over the first logical PDCP connection 102 and after the connection change to a third PDCP protocol 136 the second parent network unit 55 according to 3 ,

The problem now is that during the encoding of the packet data control information in the first parent network unit 50 through the second PDCP protocol 135 a codebook was created, initially in the second parent network unit 55 is not available and therefore from the third PDCP protocol 136 can not be used. So now become packet data control information from the first PDCP protocol 130 in the mobile telecommunication terminal 10 using the mobile telecommunication terminal 10 codec constructed differently, so can the corresponding packet data control information from the third PDCP protocol 136 the second parent network unit 55 are not decoded or decompressed, since there is no codebook or the entries in a local codebook with those in the mobile telecommunication terminal 10 to match.

A solution to this problem is to reset the PDCP protocol units provided for the generation of the required PDCP protocols in the second superordinate network unit 55 and in the mobile telecommunication terminal 10 , In the second parent network unit 55 is nothing to do, because there the corresponding PDCP protocol unit is set up when connecting change and therefore automatically reset. In the mobile telecommunication terminal 10 On the other hand, the corresponding PDCP protocol unit must be explicitly reset, with all the codebooks it uses being deleted and the first PDCP protocol 130 is reset to its original state. This method has the disadvantage that after the connection change first again codebooks in the second parent network unit 55 and in the mobile telecommunication terminal 10 must be constructed and the first packet data control information of each type of data to be encoded initially uncoded or uncompressed and are thus transmitted inefficiently.

According to the invention, the transmission of transmission-specific information, such as the codebooks created during the established connection, is now the change of connection from the first higher-level network unit 50 to the second parent network entity 55 ,

This has the advantage of providing efficient transmission over the second air interface 91 according to 1 Even after the connection change is possible without first having to transfer the first packet data control information of each data type uncoded and thus uncompressed. The transmission-specific information is thereby at the connection change of the first parent network unit 50 either directly via the seventh fixed network connection 87 or via the fifth fixed line connection 85 , the highest network unit 60 and the sixth landline connection 86 transferred to the second parent network unit. The resulting additional burden of said landline connections 85 . 86 . 87 when changing the connection are not significant because in small codebooks, the amount of data to be transmitted is small and the said landline connections 85 . 86 . 87 allow a much higher data rate than the second air interface used 91 between the mobile telecommunication terminal 10 and the second base station 30 ,

It can also be provided, already before or during establishment of the connection by the mobile telecommunication terminal 10 the first parent network entity 50 to signal whether in the case of a connection change the transmission-specific information from the first higher-level network unit 50 to be transmitted to the corresponding new parent network unit, or whether the PDCP protocol unit in the mobile telecommunication terminal 10 as described should be reset. It can also be provided that on the part of the first parent network unit 50 the mobile telecommunication terminal 10 is signaled, in case of a connection change, the transmission-specific information from the first higher-level network unit 50 to the second parent network entity 55 to be sent. In this case, corresponding signaling information of one of the first parent network unit could 50 to the mobile telecommunication terminal 10 transmitted message to provide a radio carrier for the connection to be established, this message according to the UMTS standard also referred to as "Radio Bearer Setup" message.

Another possibility is to carry out a corresponding signaling immediately before or during the connection change to be made.

The invention is based on the concrete and exemplary scenario that the mobile telecommunication terminal 10 with units of the mobile network 1 like the first base station 25 , the first parent network entity 50 and the highest network entity 60 about the necessary physical and logical connections, in particular those of the first PDCP protocol 130 and the second PDCP protocol 135 realized first logical PDCP connection 102 between the mobile telecommunication terminal 10 and the first parent network entity 50 , is connected and a data transfer, so an exchange of packet data units takes place via these connections.

In doing so lay the first PDCP protocol 130 and the second PDCP protocol 135 because of their functionality, transmission-specific information required for compressing and manipulating the payload data and the packet data control information. To ensure correct functioning of the two PDCP protocols mentioned above 130 . 135 Part of this transmission-specific information must be allowed in the two PDCP protocols 130 . 135 be synchronized or even the same. Switches the mobile telecommunication terminal 10 now the radio cell in the mobile network 1 , for example due to movement of the mobile telecommunication terminal 10 from the transmission range of the first base station 25 , in a new radio cell, a connection change is performed and a new physical connection between the mobile telecommunication terminal 10 and the second base station 30 built, which spans the new radio cell. The new physical connection corresponds to the second air interface 91 according to 1 and 3 , In 3 is the connection of the mobile telecommunication terminal 10 with the second parent network entity 55 over the second base station 30 represented, wherein like reference numerals denote like elements as in 2 , This is the second base station 30 according to 3 over the second fixed network connection 82 with the second parent network entity 55 or their RLC protocol, here as the third RLC protocol 126 is marked. The second parent network unit 55 is like the first parent network entity 50 constructed and points in a similar way to the third RLC protocol 126 the third PDCP protocol 136 on. The second base station 30 is in the mobile network 1 as described with the first parent network entity 50 different second parent network entity 55 connected. Thus, also the logical connections between the mobile telecommunication terminal 10 and the second parent network entity 55 rebuilt. It is between the first RLC protocol 120 and the third RLC protocol 126 a second logical RLC connection 103 built up. Between the first PDCP protocol 130 and the third PDCP protocol 136 becomes a second logical PDCP connection 104 built up. Thus, the first logical PDCP connection 103 through the second logical PDCP connection 104 replaced. This must be in the second parent network unit 55 the third PDCP protocol 136 after the connection change, once again be generated.

Now to a correct flow of data over the second logical PDCP connection 104 To enable, first, the first PDCP protocol 130 in the mobile telecommunication terminal 10 and the third PDCP protocol 136 in the second parent network unit 55 be synchronized again. One method is to reset the first PDCP protocol 130 in the mobile telecommunication terminal 10 in a defined initial state, the output state of the newly created at the connection change third PDCP protocol 136 corresponds to the first PDCP protocol 130 and the third PDCP protocol 136 then contain the same transmission-specific information.

According to the invention, however, a method is proposed that the transmission-specific information of the second PDCP protocol 135 from the first parent network entity 50 to a third PDCP protocol entity in the second parent network entity 55 transfers to the third PDCP protocol 136 with the transmission-specific information of the second PDCP protocol 135 to create. A reset of the first PDCP protocol 130 is not necessary then. This allows the compression methods of the first PDCP protocol 130 and the second PDCP protocol 135 continuously also between the first PDCP protocol 130 and the third PDCP protocol 136 without the latter two PDCP protocols 130 . 136 reset. This leads to a considerable data reduction on the second air interface 91 against a reset of the first PDCP protocol 130 and the third PDCP protocol 136 because the transmission-specific information is not newly created and gradually over the second air interface 91 only the same or similar status of the transmission-specific information in the first PDCP protocol 130 and in the third PDCP protocol 136 to reach, as to the end of the connection of the mobile telecommunication terminal 10 with the second parent network entity 55 had been achieved.

By way of example, the relevant methods for changing the connection from the radio cell of the first base station become exemplary 25 to the radio cell of the second base station 30 described.

When establishing the connection between the mobile telecommunication terminal 10 and the units 50 . 60 the mobile network 1 over the first base station 25 be between these units 50 . 60 the mobile network 1 and the mobile telecommunication terminal 10 negotiated various parameters for setting up the connection. These parameters also include the compression algorithm used to compress the protocol control information, the allowed length of the codebooks, and the quality of service of the connection.

In accordance with the invention, this parameter negotiation can also be added with a parameter that determines whether or not the first higher-level network entity changes during the connection 50 the PDCP protocol generated in the new superordinate network unit is to be reset to a new superordinate network unit generated by the first superordinate network unit, or the previously existing and already established transmission-specific information from the first superordinate network unit 50 to be transferred to the new parent network entity. The signaling required for the parameter negotiation can in the simplest case be done with one bit, the one to the first higher-level network unit 50 added to the message to be sent for the parameter negotiation or one of the first parent network entity 50 is added to the message to be sent for the parameter negotiation, and whose two states signal the information "PDCP protocol is reset" or "transmission-specific information is transmitted on connection change". In this example, the bit is set to "transmission-specific information is transmitted on connection change".

Packet data units generated by an application become the first parent network entity 50 transmitted by a TCP and an IP protocol to the corresponding subordinate in the layer sequence PDCP-Potokolleinheit, compressed by this and then to the corresponding in the layer sequence of the PDCP protocol unit subordinate second RLC protocol 125 to hand over. The packet data units are further included in the PDCP protocol unit of the first higher-level network entity 50 as long as in a cache 160 according to 4b) saved until the implementation of the second RLC protocol 125 responsible RLC entity of the first parent network entity 50 the correct transmission of the packet data units to the mobile telecommunication terminal 10 acknowledged. Let there be (m-1) packet data units from the PDCP protocol unit of the first higher-level network unit before the point in time at which the connection change takes place 50 compressed to its RLC unit passed and acknowledged by this. Another 6 packet data units m, m + 1, ..., m + 5 have already been transferred to this RLC unit, but have not yet been acknowledged and are therefore still in the buffer 160 , There are the packet data units m, m + 1, ..., m + 5 with the reference numerals 161 . 162 . 163 . 164 . 165 . 166 characterized. The compression of the packet data control information became a codebook 150 created as a compression table, the n entries in this example according to 4a) having the reference numerals 151 . 152 . 153 . 154 . 155 . 156 . 157 Marked are.

At the time in which the first parent network unit 50 or the mobile telecommunication terminal 10 Initiated connection changes should now take place in the second parent network entity 55 as the new parent network entity, after the connection switch, the protocols required to maintain the data transfer, such as the third RLC protocol 126 and the third PDCP protocol 136 generated.

According to the invention then in the PDCP protocol unit of the first parent network unit 50 stored current transmission-specific information, in this example so the codebook 150 and the contents of the cache 160 from the first parent network entity 50 to the second parent network entity 55 transfer. This can be the seventh fixed network connection 87 between the two parent network entities 50 . 55 can be used if it exists, or the transmission-specific information can be transmitted via the fifth fixed network connection 85 , the highest network unit 60 and the sixth landline connection 86 from the first parent network entity 50 to the second parent network entity 55 be directed. After the transmission-specific information the third PDCP protocol 136 have passed this third PDCP protocol 136 with respect to the second logical PDCP connection 104 between the PDCP protocol units of the mobile telecommunication terminal 10 and the second parent network entity 55 an exact replica of the second PDCP protocol 135 the first parent network entity 50 directly before the connection change is and the data transmission of the packet data units can be resumed substantially directly or continued from its current state, as he had last existed before the connection change.

For the first parent network unit 50 to the second parent network entity 55 Transfer-specific information to be transmitted is the codebook 150 and the contents of the cache 160 only exemplified. In a corresponding manner, the transmission-specific information to be transmitted may alternatively or additionally also contain other information, for example information about a compression of the user data in the packet data units to be transmitted in the context of the established connection, this information being able to be formed in a corresponding manner by codebooks.

Claims (8)

Method for operating a mobile radio network ( 1 ) in which payload data between a mobile station ( 10 ) and a first base station ( 25 ), wherein the payload data is assembled before being transmitted to data units, wherein for the transmission of the data units both in the mobile station ( 10 ) as well as in one of the first base stations ( 25 ) first parent network entity ( 50 ) transmission-specific information describing a current state of the transmission is stored, that upon a connection change of the mobile station ( 10 ) from the first base station ( 25 ) to a second base station ( 30 ) with a second higher-level network entity ( 55 ) in the first parent network unit ( 50 ) stored transmission-specific information to the second parent network unit ( 55 ) in order to continue the transmission after the connection change directly from its current state, characterized in that prior to or at the connection change signaling information from the first higher-level network unit ( 50 ) to the mobile station ( 10 ) is transmitted to the mobile station ( 10 ), whether in this connection change the transmission-specific information to the second higher-level network unit ( 55 ) should be transmitted. Method according to claim 1, characterized in that control information is added to the data units before their transmission, that the control information is compressed by means of differential coding before their transmission, wherein for the coding and decoding of the control information in the mobile station ( 10 ) and in the first higher-level network entity ( 50 ) each a codebook ( 150 ), the two applied codebooks ( 150 ) have identical contents, and that with the transmission-specific information at the connection switch, the information in the first higher-level network unit ( 50 ) stored codebook ( 150 ) to the second parent network entity ( 55 ) is transmitted. Method according to claim 1 or 2, characterized in that before or during a connection setup for the transmission of the data units between the mobile station ( 10 ) and the first base station ( 25 ) a first signaling information from the mobile station ( 10 ) to the first parent network entity ( 50 ) is transferred to the first parent network unit ( 50 ), whether in a connection change to a base station with one of the first parent network unit ( 50 ) transfer the transmission-specific information to the new parent network unit different new parent network unit. Method according to claim 1, 2 or 3, characterized in that prior to or during the connection exchange a second signaling information from the mobile station ( 10 ) to the first parent network entity ( 50 ) is transmitted to the first parent network entity ( 50 ), whether in this connection change the transmission-specific information to the second higher-level network unit ( 55 ) should be transmitted. Method according to one of the preceding claims, characterized in that with the transmission-specific information at the connection change in the first higher-level network unit ( 50 ) for monitoring purposes cached data units to the second parent network unit ( 55 ) be transmitted. Method according to one of the preceding claims, characterized in that the transmission-specific information at the connection change from a unit of a convergence protocol layer ( 125 ) of the first parent network entity ( 50 ) to a unit of a convergence protocol layer of the second superordinate network unit ( 55 ) be transmitted. Method according to one of the preceding claims, characterized in that the transmission-specific information when switching connections via a fixed network ( 85 . 86 . 87 ) between the first parent network entity ( 50 ) and the second parent network entity ( 55 ) be transmitted. Method according to one of the preceding claims, characterized in that before or during a connection setup for the transmission of the data units between the mobile station ( 10 ) and the first base station ( 25 ) a first signaling information from the first higher-level network unit ( 50 ) to the mobile station ( 10 ) is transmitted to the mobile station ( 10 ), whether in a connection change to a base station with one of the first parent network unit ( 50 ) transfer the transmission-specific information to the new parent network unit different new parent network unit.

Images