DE102005053706B4 - Method for data transmission in an adaptive mobile radio system - Google Patents

Abstract

Method for transmitting data within a mobile radio network with at least two base stations (BS1, BS2) and a mobile communication terminal (KE), in which data packets (1, 7) are transmitted via a communication link to the mobile communication terminal (KE) via a first of the base stations (BS1) ) are transmitted, whereby each data packet (1, ..., 7) is assigned a respective packet number, which is transmitted together with the associated data packet (1, ..., 7), and in the event of a faulty transmission of a data packet ( 1, 7) the mobile communication terminal (KE) sends a selective repetition message (SR) to the first base station (BS1), with which incorrect data packets (3) are requested from the first base station (BS1) based on the packet numbers, characterized in that that when the communication connection changes from the first base station (BS1) to a second base station (BS2), the mobile communication terminal (KE) of the tw The base station (BS2) signals the packet numbers of the currently defective data packets (3) and the packet number last received.

Description

The invention relates to a method for transmitting data within a mobile radio network having at least two base stations and a mobile communication terminal in which data packets are transmitted via a first of the base stations to the mobile communication terminal via a communication connection, wherein each data packet is assigned a respective packet number, which is transmitted together with its associated data packet, and in the event of an erroneous transmission of a data packet from the mobile communication terminal to the first base station, a selective retransmission message is sent with the packet numbers of the erroneous data packets are requested by the first base station.

Such a method is used in the prior art with regard to the request for erroneous data packets from the transmitting base station. This type of request for erroneous data packets is also referred to as "selective reject" or "selective repeat" in the context of a so-called hybrid ARQ signaling variant. In this method, the data packets to be transmitted are provided with a packet number. The respective packet number is transmitted together with the associated data packet, often both information, namely the packet number and the data packet itself, are coded separately, since it is necessary to reliably decode the packet number, in case of faulty data packets this again from the associated base station to be able to request.

The method is known as very high throughput. However, difficulties arise with regard to the application of this method, especially in future mobile radio systems, in which it is attempted to improve the data throughput taking into account current radio channels of different users in such a way that the users, who are characterized by a particularly good carrier-to-interference and noise ratio (CIR), preferably operated. For this purpose, the fading of a radio channel is used in the simplest case, which itself brings a variation of the CIR ratio with it. However, the variance of the CIR ratio can also be actively increased by so-called "self-organized beamforming". "Self-organized beamforming" is a process in which, for example, pseudorandom beamforming, i. H. Varying an antenna characteristic of an associated base station increases the variation in the CIR ratio, resulting in a strong variance of the CIR value in the downlink for each individual user in the mobile radio system. The connecting element of these adaptive methods is the presence of an uplink feedback to the base station assigned to the mobile communication terminal, in which the mobile communication terminal signals current CIR values to this base station.

Taking into account several mobile radio cells, which are each spanned by a base station, there is the effect that due to the adaptive procedure no exact cell boundary can be defined more. Rather, in the area between adjacent mobile radio cells, a good CIR ratio occurs randomly with different mobile radio cells. In order to make the most of the advantages of adaptive transmission methods, such as self-organized beamforming, it is necessary to transmit selectively from the base station to one or the other mobile radio cell. A change between two base stations must be very fast, so that the radio channel to be used between the measurement of the CIR value and the transmission of data packets can not change significantly. Since, in the adaptive method, each mobile radio cell autonomously makes the decision about the best users, there is no information about previous transmissions in an adjacent mobile radio cell. H. a continuation of the transmission of data packets by a new base station is fundamentally difficult. These difficulties are further increased if common error algorithms are used to request incorrectly received data packets, in particular the hybrid ARQ method already mentioned above.

The document 3GPP TR 25.848 V4.0.0 (2001-03), "Technical Specification Group Radio Access Network; Physical Layer Aspects of the TRA High Speed Downlink Packet Access (Release 4) ", as well as 3GPP TR 25.950 V4.0.1, describe u. a. Techniques for responding to errors in the transmission in a radio access network to a mobile radio network. In the method, each packet is assigned a packet number. If a data packet arrives at the receiver in error, the receiver sends an error message containing the number of the defective packet and the package is automatically sent again.

R2-A010017, TSG-RAN Working Group 2 Meeting # 18 "Fast Cell Selection and Handovers in HSDPA" describes a method for selecting and switching mobile radio cells by a mobile device, in particular, the correctly received data packets are confirmed and the mobile device to help Synchronization of a series of data packets in a mobile radio cell after the handover of the mobile device there. To confirm correctly received data packets, the mobile device can either confirm each packet or transmit a state of the packet series to the mobile radio cell only at station change.

GB2369961A describes a method in which a terminal of several base stations receives data packets and sends a status message in which correctly and incorrectly received packets are named. In response to such a message, a base station transmits data packets, the lowest number of data packets now transmitted designating the data packet for which no acknowledgment has yet been received. In doing so, the base station relies on both the status message of the terminal and status messages received from other base stations. In the case of handover of a terminal from one base station to the next base station, the next base station of a series of packets first transmits the packet following the packet for which a status message already exists.

Proceeding from this, the object of the invention is to further develop the method mentioned above in such a way that it can be used in adaptive mobile radio systems.

This object is achieved in the method mentioned above in that when changing the communication link from the first base station to a second base station, the mobile communication terminal of the second base station signals the packet numbers of the currently faulty data packets and an acknowledgment of the last received packet number.

In the simplest case, therefore, only the last received packet number is signaled in a change from the first base station to the second base station. This is the case when previous transmissions of data packets from the first base station to the mobile communication terminal have all been error-free and thus no so-called SR message has been sent to the first base station.

By signaling both the last received data packet by its associated packet number and additionally the currently faulty data packets, the second base station, which takes over the communication link to the mobile communication terminal of the first base station, enabled to continue the communication connection continuously.

In contrast to the conventional hybrid ARQ method, in which only certain data packets are acknowledged to be successful with respect to the first base station, the acknowledgment then including all data packets also with smaller packet numbers, according to the invention, the last successfully received data packet is the second one Base station signals. It is then able to continue the data transmission over the communication link to the mobile communication terminal with the appropriate data packet. At the same time, the signaling of the currently faulty data packets causes them not to be deleted in a transmission queue of the second base station, but to be kept ready for a new transmission to the mobile communication terminal. The background to this is that in an adaptive transmission method using, for example, "self-organized beamforming" the information about faulty data packets, which basically signals the mobile communication terminal to the first base station, must also be communicated to the second base station.

The faulty data packets and the last received packet number are preferably signaled in a signaling message. This message then contains all the information that the second base station needs to continue the communication connection to the mobile communication terminal.

This embodiment variant brings about a cost-effective summary of signaling messages for realizing a rapid cell switching or switching from a first to a second base station.

Embodiments of the invention will be explained in more detail with reference to the drawing. Show it:

1 1 is a schematic representation of a time profile of signaling messages between a base station on the one hand and a mobile communication terminal on the other hand, within a mobile radio network according to the prior art,

2 a schematic representation of a time course of signaling messages between two base stations on the one hand and a mobile communication terminal on the other hand within a mobile radio network according to the invention and

3 a schematic representation of an alternative time course of signaling messages between two base stations on the one hand and a mobile communication terminal on the other hand within a mobile network according to the invention.

In the 1 is generally illustrated in what manner according to the known SR Algorithm data transmission from a base station BS1 to a mobile communication terminal KE by Statten goes. In this case, for example, a confirmation message ACK1 is sent from the mobile communication terminal KE to the base station BS1 at regular intervals, which causes all data packets that have been received without error to be cleared in a transmission queue of the base station BS1. In the present embodiment, based on the 1 is explained, first, a first data packet 1 is sent from the base station BS1 to the mobile communication terminal KE, but received there incorrectly. The base station BS1 continues with the data transmission by sending a data packet 2 to the mobile communication terminal KE. In the present exemplary embodiment, after receiving the second data packet 2, the mobile communication terminal KE issues an SR message to the base station BS1, specifically in the next provided off-link feedback. Thus, the base station BS1 is informed that the first data packet 1 is to be sent again to the mobile communication terminal KE.

The base station BS1 continues with the transmission of data packets 3, 4. After transmission of the data packet 4 to the mobile communication terminal KE, the SR message relating to the faulty first data packet 1 is received, after which the first data packet 1 is sent again from the transmission queue of the base station BS1 to the mobile communication terminal KE.

Subsequently, a data packet 5 is transmitted from the base station BS1 to the mobile communication terminal K. I'm in the 1 illustrated embodiment, the mobile communication terminal KE after error-free reception of the first data packet 1 sends a confirmation message to the base station, which now all data packets with a packet number <2 have been received error-free. Then the first data packet 1 is deleted in the transmission queue of the base station BS1. This is followed by a transmission of a sixth data packet 6 to the mobile communication terminal KE, which itself now transmits a confirmation message to the base station BS1 that all data packets with a packet number <6 have been received without error. Then, in turn, the transmission queue of the base station BS1 is adjusted, which now only includes the data packet 6 and another, to be sent to the mobile communication terminal KE data packet 7.

In principle, this method can also be used in adaptive mobile radio networks in which a change takes place between the first BS1 and a second base station BS2 within a mobile radio connection. However, in order to allow the second base station BS2 to continue to send data continuously to the mobile communication terminal KE, the current status of the data transfer to the mobile communication terminal KE is signaled to it. This happens because information about the last error-free received data packet and information about currently to be requested new, erroneous data packets is transmitted.

The 2 and 3 each show schematically data transmission operations or signaling between four components involved in a mobile radio system, namely a gateway GW, the first base station BS1, the second base station BS2 and the mobile communication terminal KE. For each of the components gateway GW, the first base station BS1 and the second base station BS2, it is shown which changes result in respect of their send queues, wherein an output send queue with five data packets 1,..., 5 is assumed. Following the use of the reference numbers in the 1 Reference numerals for function-like components such as the base station BS1 and the data packets 1, 2 and 3 used in the same sense.

In both figures, the first two data packets are transmitted without errors, after which the communication terminal KE of the first base station BS1 signals this error-free data transmission in a first acknowledgment message ACK2. In the exemplary embodiment, it is assumed that within the first three of the four data frames of the communication terminal KE shown in the figures, the first base station BS1 has the better channel properties, while in the fourth data frame a communication connection between the mobile communication terminal KE and the second base station BS2 than that , with better channel properties.

The acknowledgment message ACK2 is forwarded from the first base station BS1 to the gateway GW. After receiving the confirmation message ACK2, the first base station BS1 deletes the first two data packets 1, 2 in its transmission queue. The same happens on the part of the gateway GW after receipt of the acknowledgment message ACK2.

In a next step, the next two data packets 3, 4 are sent to the mobile communication terminal KE by the first base station BS1, the data packet 3 being received in error due to deteriorated channel properties. From the third data frame to the fourth data frame of the mobile communication terminal KE, a change takes place for the communication connection to the second base station BS2. In the course of this change, the mobile communication terminal KE sends out a confirmation message ACK4 together with an SR message SR3, the latter stating that the third data packet 3 is to be sent again to the mobile communication terminal KE, but this time not from the first base station BS1 but from the second base station BS2. On the basis of the acknowledgment message ACK4, the fourth data packet 4 can be deleted in the transmission queue of the second base station BS2 and in a next transmission process to the mobile communication terminal KE both the third data packet 3 and the new data packet 5 are sent to the mobile communication terminal KE.

The second base station BS2 is therefore informed by direct signaling from the mobile communication terminal KE from the beginning of the communication connection, which data packets are to be sent again to the communication terminal KE, as previously had a faulty transmission, and in which data packet, the regular data transmission must be continued , The acknowledgment message ACK2, which is in principle forwarded by the gateway GW to all base stations eligible for a communication connection with the mobile communication terminal KE, can thus be ignored by the second base station BS2, since this has already directly received signaling of the required information.

The 3 is different from the 2 exclusively by the fact that the third data packet 3 is transmitted error-free to the mobile communication terminal KE, ie also here is a change of the communication link from the first base station BS1 to the second base station BS2 instead, but without erroneous data packets are to be sent again. In such a case, the mobile communication terminal KE signals in the confirmation message ACK4 of the second base station BS2 that data packet with which a data transmission is to be continued, in the present case the fifth data packet 5.

Thus, the method differs according to the 3 of the prior art method, inter alia, as follows: Also in the prior art, for example, at regular intervals, a confirmation message, such as the acknowledgment messages ACK2 and ACK4, is sent to the associated base station. According to the invention, the signaling of the last received data packet takes place in the case of a change from the first base station BS1 to the second base station BS2 out of the series signaling the last received data packet.

Claims (2)

Method for transmitting data within a mobile radio network with at least two base stations (BS1, BS2) and a mobile communication terminal (KE), in which data packets (1, 7) via a first of the base stations (BS1) via a communication connection to the mobile communication terminal (KE ), wherein each data packet (1, ..., 7) is assigned a respective packet number, which is transmitted together with its associated data packet (1, ..., 7), and in the event of a faulty transmission of a data packet ( 1, 7) from the mobile communication terminal (KE) to the first base station (BS1) a selective repeat message (SR) is sent, with the basis of the packet numbers erroneous data packets (3) from the first base station (BS1) are requested, characterized that when changing the communication link from the first base station (BS1) to a second base station (BS2), the mobile communication terminal (KE) of z wide base station (BS2) signals the packet numbers of the currently faulty data packets (3) and the last received packet number. A method according to claim 1, characterized in that the faulty data packets (3) and the last received packet number are signaled in a signaling message.

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