DE10245674B4 - Method for transmitting data packets in a radio communication system, radio communication system and station for a radio communication system - Google Patents

Abstract

Method for transmitting data packets in a transmission chain of a radio communication system, in which
A first station (S1) receives two data packets (P1, P2) in succession,
- The first station (S1) after receiving each data packet (P1, P2) performs a detection of the received data of the respective data packet
- And before the detection of the first data packet (P1) caused by the second data packet (P2) disturbance (I) of the reception of the first data packet at the first station (S1) is at least partially compensated.

Description

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

at Radio communication systems is a data transmission by means of electromagnetic waves. This is a high-frequency carrier frequency modulated by a signal corresponding to each data to be transmitted. Known radio communication systems are, for example, radio relay and mobile. In mobile radio systems is at least a part of Subscriber stations not stationary.

In Radio communication systems is often a transmission of data packet by packet. One speaks of so-called data packages. A special application for the transmission of data packets in radio communication systems is the transmission of the packages in a transmission chain, the by a plurality of transmitting and receiving stations arranged in the chain is formed. It receives every station within the transmission chain Data packet from the previous station and sends it to the next station of the chain. This way you can Data packet transmitted from a start station to a destination station who are at the beginning or end of the transmission chain. The packet transfer takes place in several jumps, with each jump being the distance between two stations of the transmission chain traveled becomes. One speaks in this context of so-called "multihop systems".

In A multihop system becomes data packets of the respective connection between the starting station and the destination station one after the other transmitted to individual stations or nodes of the transmission chain. Each station receives while that of the predecessor station modulated carrier oscillation, those for transfer the data packet data demodulates the carrier wave and tries to transfer those to her To recognize data correctly. In this case, the demodulated received signal according to certain algorithms known to those skilled in the most probable assigned date and assumes that this date is actually sent out has been. This winning of the originally sent data from the received carrier frequency is referred to herein as the "detection" of the data. This is often referred to as "decoding" a station has detected the received data, it takes in turn again a processing of this data for a subsequent transmission to the next subsequent station in the transmission chain in front. This concludes a new modulation and coding of the transmission frequencies provided for the transmission dependent on from the ones to be transferred, previously detected data.

There every station in the transmission chain must first detect the data received from it to them subsequently be forwarded to the subsequent station, and the detection faulty can not be guaranteed that at the destination station actually the original arrive from the start station sent data error-free. This Problem is the bigger, ever more stations within the transmission chain available.

In Boyer et al .: "A Comparison of Relaying Models for Multihop Channels ", Source: Internet September 25, 2002, Chapter 5, is described as being between the transmissions of the same signals by several stations within a transmission chain comes to interference. There it is suggested these interferences by usual Equalization measures to eliminate. Furthermore, it is proposed that the same emissions Signals through several stations, which are at a receiving Overlay station, Receiving side by Diversity Combining, so a combination the differently distorted and delayed versions of the received Signals to process together.

Of the Aspect of diversity combining within a multiple jump chain is also in John Boyer et. al: "A Theoretical Characterization of the Multihop Wireless Communications Channel with Diversity ", IEEE Global Telecommunications Conference GLOBECOM '01, Vol. 2, November 2001, p. 841-845.

Of the Invention is based on the object, the quality of the detection of a data packet to improve by receiving the data packet receiving station.

These The object is achieved by a method according to claim 1, a radio communication system according to claim 12 as well as a station for a radio communication system according to claim 13 solved. advantageous Training and developments of the invention are the subject of dependent claims.

The inventive method for transmitting data packets in a radio communication system provides that a first station receives two data packets in succession. The first station, after receiving each data packet, detects the received data. Before the detection of the data of the first data packet is caused by the second data packet Stö tion during the reception of the first data packet by the first station at least partially compensated.

The Considered in the invention, that during the transfer of data packets, the receipt of a data packet by the simultaneous transmission another packet of data to another receiving station done, disturbed becomes. The invention takes advantage of the fact that both the first and also the second data package, albeit at different times, be received from the first station. As soon as both data packets or receive the signals corresponding to them from the first station were it possible to the disturbing river the second data packet to the reception of the first data packet subsequently compensate.

The disorder the reception of the first data packet by the second data packet may be due in particular to the fact that the second data packet simultaneously to the receipt of the first data packet by the first Transfer station from a second station to a third station becomes.

The Compensation of the fault the first data packet through the second data packet can advantageously considering a transmission channel for the second data packet between the second station and the first station respectively. It is then advantageous to connect the transmission channel between the second station and the first station by a channel estimation determine. Methods for channel estimation are sufficient to the person skilled in the art known. A possibility to carry out the channel estimation is the transmission corresponding training symbols or training sequences. So can be provided before the transfer the two data packets to a training sequence from the second station to transfer to the third station. As the first station within radio range of the second station is (otherwise it does not interfere with Receiving the first data packet by the first station) receives the first station also the training sequence. To perform the channel estimation too can, must know the training sequence of each receiving station be. In this case, it is convenient if the training sequence of both the third station and the first station is known, so that at the same time the channel between the second and third stations through the third station and the Channel between the second station and the first station through estimated the first station can be.

Under "transmission channel" here is the propagation path to be transferred Understood data packets from the sending station to the receiving station. The transmission channel Therefore, ent does not necessarily speak of an intended connection. While the transmission of the second data packet from the second station to the third station for example, corresponds to a designated connection, this is for the transmission of the second data packet from the second station to the first station not the case. For this reason, it is therefore also about a disturbing influence of the second data packet during the reception of the first data packet by the first station.

To A development of the invention becomes data of the second data packet detected by the first station. The interference with the second data packet Upon receipt of the first data packet is determined by that the detected data of the second data packet with a through the Estimation of the Channel determined channel impulse response are evaluated. The determined disorder is used to determine a difference signal from when receiving the first data packet received by the first station received signals subtracted. Subsequently the data of the first data packet are detected in the difference signal. That means knowing the channel between the second station and the first station and the detected data of the second data packet first detected is, what proportion of the received signals of the second data packet on the sum of the received signals during the reception of the first Had data packets. After the determination of this share this becomes for determining the difference signal from the received signal mixture deducted. Because in this way at least approximately the influence of second data packet to the received signals at the first station while the reception of the first data packet is compensated, the detection the data of the first data packet can be improved.

To a first embodiment The invention first becomes the second data packet and then the first one Data packet from the first station to the second station and from transferred there to the third station. It is therefore the realization of a multihop system, its transmission chain is formed by the three stations. The interference compensation according to the invention is required to the disturbance of the second data packet transmitting from the second station to the third station upon receipt of the first data packet by the first station, the first data packet from another, previous station receives at least partially eliminate it. Because the second data packet after this first embodiment the invention already before the first data packet from the first station has been received, the interference compensation according to the invention can be carried out, as soon as the first data packet is transmitted to the first station.

According to a second embodiment of the Er invention, first the first data packet and then the second data packet are transmitted from the second station to the third station and from there to the first station. The second embodiment thus again involves a multi-hop system with a transmission chain formed by the three stations, although the arrangement of the stations within the transmission chain takes place in a different order than in the first embodiment. While in the first embodiment, the interference of the reception of the first data packet at the first station by the transmission of the second data packet by the second station, which is arranged in the transmission direction of the data packets further back in the transmission chain, as the first station, it is at the second embodiment vice versa. In the second embodiment, the second data packet, whose interference is to be compensated for the reception of the first data packet, arrives later than the first data packet to the first station. The compensation according to the invention can therefore be carried out in the second embodiment only when the second data packet has been transmitted regularly (that is, not as an interference signal) to the first station. Only then is it possible to detect the second data packet, which enables the data of the first data packet to be detected only by taking into account the interference that has already occurred previously in the event of subsequent detection of the data.

at both embodiments mentioned above The invention does not require that the three stations immediately consecutive within the transmission chain of the respective multihop system are arranged. It is also possible, that between the first station and the second station (at the first embodiment) or between the third station and the first station (at the second embodiment) at least one more, fourth station within the transmission chain is arranged.

To a development of the second embodiment of the invention is a third data packet before the first data packet from the second one Station over transfer the third station to the first station. All three data packets (ie the first, the second and the third data packet) are from the first station to a fifth Station and transferred from there to a sixth station. At the same time will be receive the first data packet from the first station, the second Transfer data packet from the second station to the third station and the third data packet from the fifth station to the sixth Transfer station. In the first station at least partial compensation takes place the disorder the reception of the first data packet, both by the second Data packet as well as caused by the third data packet, before the detection of the data of the first data packet is performed. These Further development of the invention is to a certain extent a combination of the above described first and second embodiments of the invention. It that is both a disturbing influence compensated by the transfer of the first to be transmitted through the transmission chain after the first data packet second data packet takes place, as well as the interference caused by the already before the first data packet over the transmission chain to be transferred third data packet is caused.

A Development of the invention provides that in the case that the at the transmission The stations involved in the data packets are components of a transmission chain are in which they each receive the data packets received next Forward station (corresponding to a multihop system) during one the first period of every second station of the transmission chain simultaneously sends and receives the other stations at the same time and during one second period all during the first period transmitting stations receive simultaneously and all while the first period received stations at the same time. This means that each station of the transmission chain to the same Time only either sends or receives.

The Radio communication system according to the invention and the station according to the invention for a radio communication system Show the for the implementation necessary for the process according to the invention Components on.

The Invention will be described below with reference to the figures shown in the figures Embodiments explained in more detail. It demonstrate:

1 to 3 different embodiments of the invention,

4 the transmission of multiple data packets at different times for the embodiment 3 and

5 a station according to the invention for a radio communication system.

The invention is applicable to any radio communication systems in which the reception of a first data packet by a first station is disturbed by the simultaneous transmission of a second data packet. In the following, the invention will be explained with reference to exemplary embodiments, which are multihop systems, that is, the stations involved in a transmission of the data packets form a transmission chain. Each station of the transmission chain takes one Relay function true by forwarding the data packets received from a previous station to the subsequent station.

1 shows a transmission chain of a total of four stations S0 to S3. In the 1 (and in the following 2 and 3 ) transmission chain can also be part of a longer, even more stations having transmission chain. One after the other, a second data packet P2 and subsequently a first data packet P1 are transmitted from a further station S0 via a first station S1 and a second station S2 to a third station S3. At the same time, only every second station within the transmission chain transmits while the remaining stations are receiving. In 1 the situation is shown in which the further station S0 and the second station S2 each transmit one of the data packets, while the first station S1 receives the first data packet P1 and the third station S3 receives the second data packet P2. Here only the reception of the first data packet P1 by the first station S1 will be considered in more detail. The received signals of the first data packet P1 overlap with interfering signals I, which are due to the transmission of the second data packet P2 from the second station S2 to the third station S3. Before the first station S1 carries out a detection of the first data packet P1 received by it, the interference I is compensated in the received signal mixture. The first station S1 is known both a first channel CH1 between the further station S0 and the first station S1 and a second channel CH2 between the second station S2 and the first station S1. The transmission of the first data packet P1 takes place via the first channel CH1, and the interference control I of the reception takes place via the second channel CH2 at the first station S1. The knowledge of the channels CH1, CH2 is obtained by the transmission of corresponding training sequences which are transmitted on the one hand from the further station S0 to the first station S1 and on the other hand from the second station S2 to the third station S3 before the transmission of the data packets P1, P2 is performed , The execution of a channel estimation based on a training sequence known to the receiver is known to the person skilled in the art and will not be explained further here.

The first station S1 stores the second data packet P2 that it already has to an earlier Time from the other station S0 has received, until, until it also receives the first data packet P1 from the further station S0. there the second data packet P2 is stored in the first station S1 in the form of digital values. That means the corresponding ones Received signals are demodulated beforehand and a detection of the Data of the second data packet P2 is performed in the first station S1.

To the time at which the first station S1 the first data packet P1 receives from the further station S0 is the first station S1, which simultaneously receives the second data packet P2 from the second Station S2 is transmitted to the third station S3. thats why She also announced that on receipt of the first data packet P1 the disorder I, which is due to the second data packet P2. It is the first one Station S1 is therefore possible the previously detected and stored in the first station S1 data of the second data packet P2 corresponding to the second channel CH2 To evaluate channel impulse response, so that at least approximately a determination of the interference of the second data packet P2 to the received signal at the first Station S1 takes place. The interference I determined in this way becomes subsequently from that actually Subtracting received signal mixture, creating a difference signal is determined. This difference signal is then used as the basis of Detection of the data of the first data packet P1 by the first station S1 used. In the manner described, the detection quality for the first Data packet P1 improved.

5 shows the structure of the first station S1. An antenna A is connected to a transceiver Tx / Rx. The transmitting and receiving unit Tx / Rx is connected to a detection unit DET. The detection unit DET has a channel estimator CHE, a memory MEM and a detector D. First, the first station S1 performs, with the channel estimator CHE, a channel estimation of the first and second channels CH1, CH2 on the basis of corresponding training sequences received via the antenna A. Subsequently, the second data packet P2 is transmitted from the further station S0 to the first station S1. Due to the knowledge of the first channel CH1, the data of the second data packet are detected, which are subsequently stored in the memory MEM. At a later date, the in 1 illustrated transmission of the first data packet P1 from the further station S0 to the first station S1 and the second data packet P2 from the second station S2 to the third station S3. The superimposed sum signal is received by the transmitting and receiving unit Tx / Rx. From this sum signal, the interference signal I caused by the transmission of the second data packet P2 is subtracted, before a detection of the data of the first data packet P1 by the detector D takes place. The interference I is determined on the basis of the data stored in the memory MEM data of the second data packet P2, wherein the knowledge of the second channel CH2 is taken into account.

2 shows a second embodiment of the invention, in which the illustrated transmission chain of a multihop system five stations S1 to S5. A first data packet P1 is transmitted before a second data packet P2 via the five stations in the order second station S2, third station S3, fourth station S4, first station S1 to the fifth station S5. Same reference numerals as in 1 describe similar objects. As with the other embodiments, the stations S1 to S5 may be either fixed stations or mobile stations.

When in 2 illustrated embodiment, the reception of the first data packet P1 at the first station S1 is disturbed by the simultaneous transmission of the second data packet P2 between the second station S2 and the third station S3. It is, however, different than in 1 , no immediate compensation of the disturbance I possible because the first station S1 has no knowledge of the data of the second data packet P2. For this reason, the first station S1 waits to detect the data of the first data packet P1 until at a later time it receives the second data packet P2 forwarded from the third station S3 to the fourth station S4 from the fourth station S4. Subsequently, the compensation of the disturbance I takes place on the basis of 1 and 5 explained way. This means that in this case the receiving signal mixture is stored in analog form on receipt of the first data packet P1 by the first station S1 in the memory MEM of the first station S1 (see FIG 5 ). Only when the second data packet P2 is later received by the first station S1 and the corresponding data has been detected can the first station S1, knowing the second channel CH2, subsequently determine the probable interference I during the reception of the first data packet P1. The determined disturbance I is in turn subtracted from the stored signal mixture and the detection of the data of the first data packet P1 takes place within the difference signal determined in this way.

In a modification of the second embodiment in FIG 2 the first data packet P1 is already detected before the execution of the interference compensation, re-coded and transmitted to the fifth station S5. In this way, it is not necessary to wait for the forwarding of the first data packet P1 until the second data packet P2 hits the first station S1. Only subsequently (ie after the forwarding of the first data packet P1, which is not compensated for the disturbance), is a new detection of the data of the first data packet carried out in the first station S1. This happens as soon as the second data packet P2 has been forwarded from the fourth station S4 to the first station S1. Now it can be detected by comparing the results of the two detections of the first data packet S1 (with and without interference compensation), whether the first detection was faulty or not. If an error is detected, the first station S1 can transmit the now corrected first data packet again to the fifth station S5. It is then not necessary for the relevant data packet to be retransmitted over the entire transmission chain if an error occurs. This can reduce the time required for retransmission.

3 shows a third embodiment of the invention, in which the transmission chain is formed by six stations S1 to S6. A third data packet P3 is transmitted in succession from a second station S2 via a third station S3, a fourth station S4, a first station S1, a fifth station S5 to the sixth station S6 before a first data packet P1 and a second data packet P2. As with the other embodiments, at the same time, only every other station within the transmission chain transmits one data packet while the other stations are receiving. In 3 the state is shown in which the first data packet P1 is transmitted from the fourth station S4 to the first station S1. Since the second data packet P2 is simultaneously transmitted from the second station S2 to the third station S3, a fault I1 occurs at the first station S1, in accordance with the second exemplary embodiment 2 , At the same time, the third data packet P3 is also transmitted from the fifth station S5 to the sixth station S6. This results in a disturbance I2 at the first station S1, according to the first embodiment 1 , When in 3 illustrated third embodiment is now a simultaneous compensation of the two disturbances I1, I2, before a detection of the data of the first data packet P1 takes place in the first station S1. The determination of the interference I1, I2 takes place on the basis of 1 and 2 respectively explained manner.

Even though the inventive method the embodiments considered here was explained only with regard to the respective first station S1, Is it possible, that the inventive method involved in several or even all of the transmission chain Stations is performed.

4 shows for different times t0 to t3 the transmission of the three data packets P1 to P3 on the in 3 illustrated transmission chain of stations S1 to S6. Those columns in 4 , above which is the reference numeral of the respective station S1 to S6, it can be seen which of the stations is currently receiving one of the data packets. The columns between each two stations indicate which data packet is currently being transmitted between the respective neighboring stations. At the first time t0, the second station S2 receives the second data packet P2 from an in 3 not shown further station. The fourth station S4 receives from the third station S3 the first data packet and the fifth station S5 receives the third data packet P3 from the first station S1. At a second time t1, the third station S3 receives the second data packet P2 from the second station S2, the first station S1 receives the first data packet P1 from the fourth station S4 and the sixth station S6 receives the third packet P3 from the fifth station S5. At the third time t2, the second station S2 receives a (in 3 not shown) fourth data packet P4 from the other station, the fourth station S4 receives the second data packet P2 from the third station S3 and the fifth station S5 receives the first packet from the first station S1, while the sixth station S6 the third packet P3 one also in 3 further station of the transmission chain, not shown. At the fourth time t3, the second station S2 transmits the fourth data packet P4 to the third station S3 and the fourth station S4 transmits the second data packet P2 to the first station S1, while the fifth station S5 transmits the first data packet P1 to the sixth station S6.

The in 3 shown state corresponds to the second time t1 in 4 , However, this concerns the respect 2 described modification of the second embodiment of the invention, in which data packets received by one of the stations are transmitted to the next station in the next time interval. In this modification, the inventive compensation of a disturbance, which is caused by a subsequent data packet, as above at 2 described, not before the forwarding of the disturbed data packet, but thereafter, namely before the implementation of a second detection thereof, already forwarded data packets.

If the compensation of the disturbance caused by a subsequently transmitted data packet is to be carried out before the forwarding of the previous data packet, it is deviated from 4 required to store the received data packets between until the interfering data packet has also been received from the same station. This leads to certain delays in the transmission of the packets. This delay can be reduced by applying the described interference compensation only to every other data packet received by one of the stations. Furthermore, it is possible to carry out the interference compensation only in every second station within the transmission chain.

Claims (13)

Method for transmitting data packets in a transmission chain a radio communication system in which - a first station (S1) two Receives data packets (P1, P2) in succession, - the first station (S1) after the reception of each data packet (P1, P2) a detection of the received data of the respective data package - and before the detection of the first data packet (P1) a fault caused by the second data packet (P2) (I) the reception of the first data packet at the first station (S1) at least partially compensated. The method of claim 1, wherein the receiving of the first data packet (P1) caused by the second data packet (P2) disorder (I) is conditional on the second data packet being simultaneously for receiving the first data packet by the first station (S1) from a second station (S2) to a third station (S3) becomes. Method according to claim 2, wherein the compensation the disorder (I) of the first data packet (P1) by the second data packet (P2) considering a transmission channel for the second data packet between the second station (S2) and the first Station (S1) takes place. Method according to Claim 3, in which the transmission channel (CH2) between the second station (S2) and the first station (S1) through a channel estimation is determined. The method of claim 4, wherein - Dates of the second data packet (P2) detected by the first station become, - the disorder (I) by the second data packet (P2) upon receipt of the first data packet (P1) is determined by the fact that the detected data of the second Data packets with a value determined by estimating the channel (CH2) Be evaluated channel impulse response, - the detected disturbance (I) for determining a difference signal from when receiving the first Data packets (P1) from the first station (S1) received received signals is subtracted - and subsequently the data of the first data packet (P1) detected in the difference signal become. Method according to one of claims 2 to 5, wherein first the second data packet (P2) and then the first data packet (P1) from the first station (S1) to the second station (S2) and from there is transmitted to the third station (S3). Method according to one of claims 2 to 5, wherein first the first data packet (P1) and then the second data packet (P2) from the second station (S2) to the third station (S3) and from there transferred to the first station (S1) becomes. Method according to Claim 7, in which the data packets (P1, P2) are transmitted from the third station (S3) via a fourth station (S4) are transmitted to the first station (S1). A method according to claim 7 or 8, wherein - a third Data packet (P3) before the first data packet (P1) from the second station (S2) over the third station (S3) is transmitted to the first station (S1), - all three Data packets (P1, P2, P3) from the first station (S1) to a fifth station (S5) and from there to a sixth station (S6) transmitted become, - to the same time the first data packet (P1) from the first station (S1) receive the second data packet (P2) from the second station (S2) to the third station (S3) and the third data packet (P3) from the fifth station (S5) to the sixth station (S6) becomes - and in the first station (S1) an at least partial compensation the disorder the receipt of the first data packet (P1) by both the second Data packet (P2) as well as through the third data packet (P3) before the Detection of the data of the first data packet (P1) takes place. Method according to one of the preceding claims, in the data packet received first from the first station (S1) (P1; P2) is stored in the first station for at least as long, until the data packet (P2; P1) received thereafter is received. Method according to one of the preceding claims, in the - the at the transmission the data packets (P1, P2) stations involved (S1 to S6) components a transmission chain are in which they each received data packets to each next Forward station, - during one first period (t1) every other station (S2, S4, S5) of the transmission chain simultaneously and the other stations (S3, S1, S6) simultaneously receive - and while a second period (t2) all during the first period Receiving stations (S2, S4, S5) received simultaneously and all while the first period receiving stations (S3, S1, S6) simultaneously send. Radio communication system with at least three stations, - whose Stations a receiving unit for successive reception of two data packets (P1, P2), - Its stations a detection unit (DET) for detecting the received data of the respective data packet (P1, P2) after receiving, - And in which the detection unit (DET) of the stations means (CHE, MEM) to at least partially Compensating one caused by the second data packet (P2) disorder (I) the reception of the first data packet (P1) before the detection of the Data of the first data packet. Station for a transmission chain a radio communication system, - with a receiving unit (Tx / Rx) for the consecutive reception of two data packets (P1, P2), - With a detection unit (DET) for detecting the received data the respective data packet (P1, P2) after reception, - whose Detection unit (DET) means (CHE), MEM) for at least partially compensating for one caused by the second data packet (P2) disorder (I) the reception of the first data packet (P1) before the detection of the Data of the first data packet, - Its detection unit (DET) means (MEM) comprises data packets received before a disturbance as long as you can temporarily save until the disturbing Data packet has also been received from the same station.