DE10230400B4 - Method for transmitting data packets in a mobile radio system and corresponding mobile radio system - Google Patents

Abstract

Method for transmitting data packets from a first transmitting station (RNC; MS1, ZS) to a mobile receiving station (UE; MS4) in a mobile radio system, in which
A connection between the first transmitting station (RNC; MS1, ZS) and the receiving station (UE; MS4) is established via a second transmitting station (B1; MS2),
First data packets (DPm) are transmitted from the first transmitting station (RNC; MS1, ZS) to the second transmitting station (B1; MS2) for transmission to the receiving station (UE; MS4),
- Information (I) about those first data packets (DPm) that were not successfully transmitted to the receiving station (UE; MS4) via the second transmitting station (B1; MS2) in the second transmitting station (B2; MS3) and / or Receiving station (UE; MS4) is determined,
The connection is transferred to a third transmitting station (B2; MS3),
- After the transfer of the connection, second data packets (DPm ') from the first transmitting station (RNC; MS1, ZS) to the third transmitting station (B2; MS3) ...

Description

The The invention relates to a method for transmitting data packets in a mobile radio system, as well as a corresponding mobile radio system.

In mobile radio systems such as GSM (Global System for Mobile communications) and UMTS (Universal Mobile Telecommunications System), data and data packets from the fixed network are transmitted to receiving stations by means of transmitting stations via an air interface. In 1 a conventional UMTS is shown schematically and simplified. The fixed network CN is connected to the UTRAN (Universal Terrestrial Radio Access Network) by means of data lines Iu. The UTRAN consists of several subsystems RNS (Radio Network Subsystem), each of which has a data line Iu to the fixed network CN. Connected to each data line Iu is always a controller RNC (Radio Network Controller), which in turn is connected to several base stations B by connections Iub. Each base station B can be assigned several cells (cell) of the mobile radio system (e.g. via sector antennas). The interface between UTRAN and the user equipment UE (user equipment), which is referred to as a mobile station in GSM, takes place via the interface Uu by means of a radio link. The controllers RNC of different subsystems RNS are usually connected by another interface Iur. This further interface Iur is required for a so-called handover (cell change).

During one The user device UE with at least two base stations B is soft handover connected at the same time, the different controllers RNC can be assigned. Since only for data exchange between the user equipment UE and the fixed network CN a connection Iu needed the data flow from only one controller RNC, called SRNC (Serving RNC). If the two base stations B are to be assigned to different controllers RNC, is only one of the RNC controllers of the SRNC, during the second controller is referred to as DRNC (Drift RNC). The DRNC called controller handles its data transmission from and to the fixed network CN about the further interface Iur and thus via the controller SRNC.

In Every controller RNC is connected to an RLC (radio Link Control) with the help of a memory RS, in which in addition to the Data packets are saved, which data was sent again are to be sent or have yet to be sent. With a soft handover this status information of the data transmission is only in the controller SRNC saved. about a similar memory US for The user equipment UE also has status information and data packets Information about it stores which data it has successfully decoded and for which Data retransmission requests. If the data is successfully decoded, the user equipment UE sends one confirmation ACK (acknowledge) to the connection control RLC of the responsible controller RNC. If the decoding is unsuccessful, a NACK instead (non acknowledge) sent.

While at Soft handover at the same time a connection of the user equipment UE there is at least two base stations B during the hard handover the connection from a base station B to another base station B passed if the connection to the first base station B was previously ended. As well As with the soft handover, this handover can take place both between base stations B of the same controller RNC take place as well as between base stations B different controller RNC. However, an adjustment must be made after a hard handover the stored status information of the data transmission between the user equipment UE and the responsible Controller RNC take place and if necessary the memory content of the old one Controller RNC are transferred to the new controller RNC. This comparison the status information of the data transmission takes time and delays resumption of data transmission after a hard handover. High data rates are therefore not too bad to reach.

The same applies to the data rate for a quick selection of the radio cell with which the subscriber device UE wants to operate a connection. The subscriber device UE has a set of possible Radio cells to choose from which it can connect to the landline CN. The user equipment UE determines now the radio cell with the best properties and signals in the upward direction (Uplink) from which cell it wants to be supplied. This principle becomes fast Called Cell Selection (FCS). change the chosen one Cell while connection, the same problem occurs with FCS as with a hard handover. The comparison of the saved status information the data transmission must also at FCS as described in the previous paragraph. High data rates are therefore not possible with FCS.

However, future mobile communication systems will need and have to support high data rates. An example of this is High Speed Downlink Packet Access (HSDPA), which is currently being discussed by the 3rd Generation Partnership Project (3GPP) for UTRA FDD and TDD (Universal Terrestrial Radio Access Frequency Division Duplex and Time Division Duplex). In order to achieve high data rates, the control of the data transmission is shifted from the controller RNC to the base stations B, ie additional memories are stored in the base stations B. BS set up that store the data packets and the status information of the data transmission. In this way, time is saved since the transmission path between the controller RNC and the base stations B is eliminated when controlling the data transmission. With this new memory BS in the base stations B, the hard handover also takes place as previously described. Suggestions for this can be found e.g. B. in a contribution from Motorola on the occasion of the TSG-RAN Working Group 2 meeting # 18/00 in Edinburgh, from 15th to 19th January 2000, with the title "Fast Cell Selection and Handovers in HSDPA" (R2-A010017). As explained above, data transmission is resumed when the new base station B has been informed of the status of the data transmission, ie when the memory content of the old base station B has been transmitted to the new base station B. This synchronization of the status information of the data transmission between the old and new base station B takes place either via the connections Iub of the controller RNC, possibly also via the further interface Iur and / or through the subscriber device UE via the radio interface. The limits for HSDPA thus result from the finite time required for the transfer of the memory content of the old base station B (data packets and transmission status of the data packets) to the memory BS of the new base station B is required w ill.

In the EP0695053A a handover from an old base station to a new base station is described for a cellular computer device. The protocol status of the data transmission is communicated to the new base station either by corresponding information from the cellular computer device, information from the old base station or a combination of both information during the handover.

The The invention is therefore based on the object of specifying a method with that in the event of a change of the subscriber device UE-assigned cell (hard handover or FCS) has a higher data rate guaranteed can be than has been possible so far is.

This Object is with the method according to claim 1 and the mobile radio system according to claim 7 solved.

advantageous Training and further developments of the invention are the subject of the dependent claims.

At the method according to the invention for transmission of data packets from a first transmitting station to a mobile one Receiving station in a mobile radio system, is a connection between the first transmitting station and the receiving station via a second transmitting station established and first data packets from the first transmitter to the second transmitting station for transmission transmitted to the receiving station. Information about those first data packets that are not successful over the second transmitting station have been transmitted to the receiving station is in the second transmitting station and / or the receiving station determined. This Information thus gives status information about the data transmission on. A handover takes place the connection to a third transmitting station and after the handover the connection becomes second data packets from the first transmitting station transmitted to the third transmitting station and transmitted from there to the receiving station. The information about those first data packets that are not successful via the second sending station have been transmitted to the receiving station, is only after the transfer of the second data packets to the first transmitting station and / or the third Transmitting station transmitted. This procedure enables it, in the event of a connection change, such as that resulting from a handover or a Fast Cell Selection, data packets are immediately transmitted without that the third transmitting station and / or the first transmitting station about success or failure previously broadcast Has knowledge of data packets, d. H. about that determined by the second transmitting station and / or the receiving station Status information of the data transmission features. The method according to the invention can higher Ensure data rates when changing connections than this possible if, before the data transfer continues, the status information the data transmission from the second transmitting station to the third transmitting station and / or the first transmitting station transmitted becomes. This method is particularly suitable for data transfers with high data rates Like high speed downlink packet access (HSDPA).

In a first embodiment the invention is carried out of the method in a cellular mobile radio system. Here is the first transmitter station a controller, the second and third transmitter station are base stations and the receiving station is a subscriber device.

A second embodiment of the invention leads the procedure in an ad hoc network (also self-organizing network called) by. In an ad hoc network, i. H. a communication network, that too exclusively can be formed by mobile stations, is the first transmitting station a mobile station or an access station. Under an access station is to be understood as a fixed station that has access to the fixed network allows. The second and third transmitting station as well as the receiving station are mobile stations.

Preferably the second data packets do not match any of the first data packets. This ensures that no data packets are transmitted multiple times become. This increases again the data rate during the change of connection.

In an alternative embodiment of the invention, the second vote Data packets match those of the first data packets, which transmits from the first transmitting station to the second transmitting station, but not before the handover the connection from the second transmitting station to the receiving station were. With this configuration, the delivery is immediate transfer data packets of the connection, the the subscriber device already during the data transmission through would have the first broadcasting station should receive. These data packets now reach the subscriber device for the first time and even before the third transmitting station the status of the data transmission knows. This in turn increases the data rate.

Is expedient it, those of the first data packets coming from the first sending station transmitted to the second transmitting station, but not before the handover the connection has been transmitted from the second transmitting station to the receiving station, based on the expected transmission time from the first transmitting station to the second transmitting station or to the receiving station to investigate. Based on the estimated transmission time, i.e. H. based the time it takes a data packet to send from the second transmitter station after being sent by the first transmitter station or to be received by the receiving station, the first Send station specify which data packets the receiving station never could reach, even before they made the connection change have been sent from the first transmitting station. These data packets can then be transmitted from the third transmitting station without this Transmitting station over a status information of the data transmission features.

The Mobile radio system is with the for the implementation necessary components of the process.

The The invention is illustrated below with reference to the figures Embodiments explained in more detail. It demonstrate:

1 a UMTS according to the state of the art,

2 a section of a cellular mobile radio system according to the invention,

3 to 7 the sequence of data transmission when changing connections,

8th another embodiment of the mobile radio system according to the invention, in the form of an ad hoc network.

The invention is described below using a UMTS. Of course, the invention can also be used for other mobile radio systems. This applies in particular to GSM, ad hoc networks (see 8th ) and 4th generation mobile radio systems.

The same reference numerals in the 1 and 2 denote the same objects.

In the in 2 A section of a UMTS is shown, a first, a second and a third transmitting station are represented by a controller RNC, a first base station B1 and a second base station B2. There is a connection between a receiving station in the form of a user equipment UE and the first base station B1 via a transmission path 1 , Via this connection, first data packets DPm are transmitted from the fixed network CN to the user equipment UE by means of the interfaces Iu and Iub1. The controller RNC has a memory RS. The base stations B1, B2 with memories BS and the user equipment UE with memory US have a processor P with which the information I described below can be determined. The memories RS, BS, US serve to store data packets and information about the status of the data transmission of each data packet.

In The first base station B1 transmits those from the controller RNC Data packets DPm are stored in the memory BS and transmitted from there to the user equipment UE. In the first base station B1 and in the user equipment UE the processor I uses the processor P to determine the information I which of the first data packets DPm failed successfully over the first base station B1 were transmitted to the user equipment UE. This information I thus indicates for which of the first data packets DPm receives a NACK signal from the user equipment UE the first base station B1 was sent and which of the first data packets DPm transmitted from the controller RNC to the first base station B1, but not yet to the subscriber device UE were sent. The controller RNC can be based on the content of its Memory RS determine which data packets it has already sent to the first Base station B1 has transmitted and which data packets from him have not yet been sent to the first base station B1 transmitted were.

The connection quality of the connection via the transmission path drops 1 below a minimum while at the same time for a potential transmission path 2 A better connection quality is possible via the second base station B2, the transmission path is changed, ie the connection is transferred from the first base station B1 to the second base station B2. Immediately after this handover, second data packets DPm 'are already transmitted from the controller RNC to the second base station B2 and from there to the user equipment UE. These second data packets DPm 'were not previously transmitted to the first base station B1. The controller RNC can ensure this by transferring only second data packets DPm 'with identification numbers m' from its memory RS due to the transmission status of its memory RS, which it has not previously transmitted to the first base station B1. In this way, data transmission to the user equipment UE is enabled again immediately after the handover. Only after or during the transmission of these second data packets DPm 'to the subscriber device UE is the second base station B2 informed of those of the first data packets DPm that were previously unsuccessfully transmitted to the subscriber device UE via the first base station B1, ie for the subscriber device UE has sent a NACK signal to the first base station B1, or which has been stored in the first base station B1 but has not yet been transmitted to the user equipment UE. For this purpose, this information I is transmitted from the user equipment UE via the air interface and from the first base station B1 to the second base station B2 via the interfaces Iub1 and Iub2. After the transmission of the information I and the simultaneous transmission of the data packets designated by the information I via the interfaces Iub1 and Iub2, the data transmission of these data packets is made up and the mobile radio system continues the regular data transmission.

In the 3 to 7 describes the chronological sequence of the data transmission before and shortly after the transfer of the connection from the first base station B1 to the second base station B2. The tables show the contents of the memories RS, BS, US of the stations involved at different times. The first column (new) of the memory RS of the controller RNC lists identification numbers of those data packets that the controller RNC has received from the fixed network CN but has not yet transmitted to the memory BS of the first base station B1 or the second base station B2 , In each case the first column (new) of the memory BS of the first base station B1 and the second base station B2 contains identification numbers of those data packets which have been received by the controller RNC but have not yet been sent to the user equipment UE. In each case the second column (sent) of the memory RS, BS contains the identification numbers of data packets already sent, while the third column (retrans) contains identification numbers of data packets which were retransmitted after a NACK signal. In the memory US of the user equipment UE, the first column (ACK) indicates which data packets have been successfully decoded, while the second column (NACK) contains those identification numbers whose associated data packets could not be successfully decoded and for which retransmission is requested. In the following, the specification “data packet n” means the data packet with the identification number n.

According to 3 the controller transmits RNC during the connection via the transmission path 1 initially data packets 1 to 4 (sent) as the first data packets DPm (cf. 2 ) to the first base station B1. More data packets 5 to 9 (new) are still in the queue and are waiting to be sent. The first base station B1 already has data packets 1 to 3 transmitted (sent) while data packet 4 received but not yet transmitted to the user equipment UE. The user equipment UE has data packets 1 and 3 (ACK) successfully decoded, but data packet 2 was received incorrectly (NACK) and is requested again.

to better overview is not always another transfer in the following figures new data packets in parallel with the update of the memory contents shown. This parallel transmission is however possible.

In 4 the memory RS of the controller RNC remains unchanged. After the transmission of ACK signals and NACK signals from the user equipment UE to the base station B1, the data packet remains 4 ready for transmission in the first base station B1, but has not yet been transmitted. The base station B1 is now informed that the data packet 2 must be retransmitted. This data packet was received from the user equipment UE 2 not yet successfully received, so that the status "NACK" remains stored for this data packet. The information about the status "ACK" of the data packets 1 and 3 is no longer needed and has since been deleted.

If the handover takes place in this state, the result is in 5 presented situation. The memories of the first base station B1 and the user equipment UE remain unchanged. However, controller RNC is already sending new data packets 5 to 7 (sent) as second data packets DPm '(cf. 2 ) to the second base station B2 (see there in the first column). The question marks in the columns of the second base station B2 make it clear that the second base station B2 has no information about the course of the previous transmission (transmission path 1 in 2 ) has.

In 6 the data packets are already being transmitted 5 to 7 (sent) by the second base station B2, while the memories of the first base station B1 and of the user equipment UE are synchronized with the second base station B2 simultaneously (or following this transmission) (status synchronization). During the status synchronization, the status information of the data transmission stored in the memory BS of the first base station B1 is compared as information I and the necessary data packets are transmitted. So in this example the data packets 2 and 4 as well as the associated status information (Information I) during status synchronization. The memory of the user equipment UE naturally contains information about the transmission success of the data packets 5 to 7 , in addition to the status information of the data packet that is still stored there 2 ,

After the memory of the second base station B2 has been updated, the memory state of the first base station B1 can be found there accordingly (see 7 ), ie the data packet 4 in the first column and the data packet 2 in the third column: The data packet is also in the third column 6 for which the user equipment UE has requested retransmission.

According to the invention, the first data packets are first 5 to 7 transmitted via the second base station B2 before the status synchronization takes place. In comparison, the transmission of the data packets would be according to the prior art 5 to 7 only after the status synchronization.

The first base station B1 and the second base station B2 are only assigned to a single controller RNC in the exemplary embodiment shown. However, the method according to the invention can also be transferred to situations in which the first base station B1 and the second base station B2 belong to different controllers RNC (cf. 2 ). In this case, the Iur interface is also required for status synchronization.

In a further exemplary embodiment, the controller RNC knows the expected transmission time of data packets to the first base station B1 or to the user equipment UE. So he can calculate or estimate whether the data packet 4 could have been transmitted to the user equipment UE before the handover. It turns out that a transmission is as for the data packet 4 out 5 visible, could not take place before the handover, the controller RNC can of course the data packet 4 already with the data packets 5 to 7 transmit and thus additionally increases the data rate during the connection change. This case is due to the number in parentheses 4 represented in the memory BS of the second base station B2. The controller RNC can determine the expected transmission time from the maximum data rate of the transmission of the first data packets DPm from the first base station B1 to the user equipment UE and from the delay in the transmission of the first data packets DPm from the controller RNC to the first base station B1. The delay in the transmission to the first base station B1 is known to the controller RNC from the previous transmission and can be approximately 10 to 100 milliseconds. Large delay times are achieved in particular when the interface Iur is required for the transmission of data packets, ie when different controllers RNC are involved in the data transmission. If, for example, there is an expected transmission time of 100 milliseconds, the controller RNC cannot assume that data packets that it transmitted to the first base station B1 80 milliseconds (100 milliseconds minus a security margin of 20 milliseconds in this example) before the handover more could be transmitted to the user equipment UE. The controller RNC can immediately transmit these data packets together with data packets not yet transmitted to the first base station B1 to the second base station B2.

Even in an ad hoc network like the one in 8th the method according to the invention can be used. In this case, the first data packets DPm are transmitted either from a first mobile station MS1 or an access station ZS to a second mobile station MS2 and from there to another mobile station MS4 as the receiving station. The second data packets DPm 'are transmitted to a third mobile station MS3 and from there to the further mobile station MS4. An access station is a fixed station which - analogous to the RNC controller in UMTS - enables the subscriber stations of an ad hoc network to access the fixed network CN. Mobile stations MSi each have a memory S for data packets and status information for the data transmission and a processor P for determining the information I. Except for a different designation for the transmitting stations and the receiving station, the process according to the invention is in an ad hoc network as is in 8th is shown, identical to the exemplary embodiment previously described on the basis of a cellular system ( 2 to 7 ).

Claims (7)

Method for transmitting data packets from a first transmitting station (RNC; MS1, ZS) to a mobile receiving station (UE; MS4) in a mobile radio system, in which - a connection between the first transmitting station (RNC; MS1, ZS) and the receiving station (UE; MS4) is set up via a second transmitting station (B1; MS2), - first data packets (DPm) from the first transmitting station (RNC; MS1, ZS) to the second transmitting station (B1 ; MS2) are transmitted for transmission to the receiving station (UE; MS4), - information (I) about those first data packets (DPm) that are not successful via the second transmitting station (B1; MS2) to the receiving station (UE; MS4) were transmitted, is determined in the second transmitting station (B2; MS3) and / or the receiving station (UE; MS4), - the connection is transferred to a third transmitting station (B2; MS3), - after the connection has been transferred, second data packets ( DPm ') is transmitted from the first transmitting station (RNC; MS1, ZS) to the third transmitting station (B2; MS3) and from there to the receiving station (UE; MS4) - and the information (I) is only transmitted after the second Data packets (DPm ') to the first transmitting station (RNC; MS1, ZS) and / or d he third transmitter station (B2; MS3) is transmitted. The method of claim 1, wherein - the implementation of the Procedure takes place in a cellular mobile radio system, - the first Transmitter station is a controller (RNC), - the second and third transmitting station Base stations (B1, B2) are - and the receiving station UE (UE) is. The method of claim 1, wherein - the implementation of the Procedure takes place in an ad hoc network, - the first transmitting station one is a mobile station (MS1) or an access station (ZS) - and the second and third transmitting station and the receiving station mobile Stations (MS2, MS3, MS4) are. Method according to one of the preceding claims, which the second data packets (DPm ') with none of the first data packets (DPm) match. Method according to claims 1, 2 or 3, in which - the second Data packets (DPm ') match those of the first data packets (DPm) that are sent by the first transmitting station (RNC; MS1, ZS) to the second transmitting station (B1; MS2) transmitted, but not before the handover the connection from the second transmitting station (B1; MS2) to the receiving station (UE; MS4) transferred were. The method of claim 5, wherein - the second Data packets (DPm ') based on the expected transmission time from the first transmitting station (RNC; MS1, ZS) to the second transmitting station (B1; MS2) or to the receiving station (UE; MS4) can be determined. Mobile radio system with a first, a second and a third transmitting station (RNC, B1, B2; MS1, MS2, MS3, ZS) and a mobile receiving station (UE; MS4) - its first transmitter (RNC; MS1, ZS) and second transmitting station (B1; MS2) are formed in this way are that first Data packets (DPm) of a connection from the first transmitting station (RNC; MS1) can be transmitted to the second transmitting station (B1; MS2), - whose second transmitting station (B1; MS2) and receiving station (UE; MS4) in this way are trained that a Information (I) about those first data packets (DPm) that are not successful over the second transmitting station (B1; MS2) transmitted to the receiving station (UE; MS4) were in the second transmitting station (B2; MS3) and / or the receiving station (UE; MS4) is determined - and has the means for transmission the information (I) to the first transmitting station (RNC; MS1, ZS) and / or a third transmitting station (B2; MS3), only after a handover the connection to the third transmitting station (B2; MS3) has been made and already second data packets (DPm ') from the first transmitting station (RNC; MS1, ZS) were transmitted to the third transmitting station (B2; MS3) and from there were transmitted to the receiving station (UE; MS4).