DE19851309C1 - Data transmission method for radio communication system - Google Patents

Abstract

The method involves using a first frequency band (FB1) for data transmission according to a TDD transmission technique. The transmission directions within the first frequency band are separated by a switch-over point. In the downlink direction, the transmission is continuous, data sequences (da) and channel measurement sequences (ma) alternating in a cyclical sequence. In the uplink direction, transmission is discontinuous in time slots separated by protective intervals.

Description

The invention relates to a method for data transmission in a radio communication system via a radio interface between a base station and subscriber stations and a such designed radio communication system.

In radio communication systems, data (for example Language, image information or other data) with the help of electromagnetic waves via a radio interface wear. The radio interface relates to a verbin between a base station and subscriber stations, the subscriber stations being mobile stations or fixed Can be radio stations. The radiation of the electromagnetic table waves takes place with carrier frequencies in the intended frequency band for the respective system. For future radio communication systems, for example that UMTS (Universal Mobile Telecommunication System) or others 3rd generation systems are frequencies in the frequency band of approximately 2000 MHz.

A TDD is used for the 3rd generation mobile radio systems (time division duplex) mode especially for data services with asymmetrical data rates required. For TDD mode should be in a first frequency band for the up and down direction a combination of TDMA (time division multiple access) and CDMA (code division multiple access) participants separation processes are used, whereby within the Time slots for both directions of transmission a burst like transmission with interim shutdown or strong transmission power reduction is used. As from DE 196 03 443 C1, EP 0 722 230 A2 and "Draft ITU system descrip tion for the UTRA TDD component ", ETSI SMG2 UMTS-L1, Tdoc  SMG2 UMTS-L1 104/98, Siemens AG, Bocholt, May 18, 1998, pp. 1-9, emerges, it is intended in TDD mode, in both Transmission directions to send radio blocks, the one  Channel measurement sequence (midamble) for channel estimation in the middle of contain two data parts.

For the targeted services with asymmetrical data rates Above all, the downward direction should allow higher data rates sen. This is for services like video on demand or internet Queries a goal suspension, since short queries each large amounts of data are to be transmitted to the subscriber station. The transmission capacity in the downward direction is therefore the Bottleneck and limits the performance of the radio Communication system.

The invention is therefore based on the object of a method and a radio communication system to indicate data transmission which is a higher transmission reach capacity in downward direction. This task will by the method with the features of claim 1 or by a radio communication system with the features of claim 11 solved. Advantageous developments of the invention are the Unteran to take sayings.

According to the invention, it is proposed for data transmission via a radio interface between a base station and Subscriber stations in the TDD transmission method for Auf- and Downward directions different transmission methods clog. This is how a transfer is to be made in the downward direction be carried out slowly, with data shares and Alternate channel measurement sequences in cyclical order and in open downward a transmission discontinuously in through Separation of time slots are carried out. By eliminating the protective distances in the downward direction the capacity of the transmission in the downward direction increases.

Since the signals from a radio station, the Base station, so each signal can go out do not overlap parts beyond the multiple-path delay. If the data shares of the individual time slots above it are separated by channel measurement sequences, so is temporal resolution of the signals easily possible.  

According to an advantageous development of the invention, a Time interval for an arbitrary access of the participants merstations is arranged near the switchover point. The order switching point always specifies a protective distance that you have to Selection of the time interval for an arbitrary access with can be used without blocking additional resources.

The base station is able to use the channel measurement sequences maximum transmission power and without overlay with data share send. This keeps intersymbol interference insignificant and the channel estimate at the participant sta tion is due to the high transmission power of the channel measurement sequences zen relieved. To further improve channel estimation, are used for channel estimation in a subscriber station Interpolated evaluations of several channel measurement sequences or extrapolated. This also allows the transmission channels to be closed fast moving subscriber stations more accurately estimated become.

To simplify the evaluation of the channel measurement sequences and for the best possible use of the resources for synchronization it is advantageous that several subscriber stations are the same use the same channel measurement sequence in time and the channel measurement sequence from the subscriber stations with different Code phases are sent. So less channel measurement sequences can be defined or a sentence from before existing channel measurement sequences, the parts of which are as strong as possible distinguish, use effectively. In the latter case network planning easier. Such channels are also measurement sequences with different code phases orthogonal, one certain time synchronization of the base stations ahead set.

Are the same channel measurements from several subscriber stations but use different code phases, so it is advantageous that with a channel estimation in the base station a cyclic correlation to channel estimation of transmissions  used by several subscriber stations becomes. The results for the individual subscriber stations are easy to separate through different measurement windows nen. To increase the measuring accuracy, several can Channel measurement sequences of a subscriber station for determining the Correction value can be used. The same applies to the reverse reversed direction of transmission.

For interference suppression, it is proposed that a Detection of simultaneously transmitted data a common Detection (joint detection) according to DE 41 21 356 A1 or a Transversal filtering according to DE 197 47 454 C1 with elimination of the strongest interference signals. For be in both modes drivable subscriber stations is advantageously a common detection algorithm for TDD and FDD over transfer method used. Through better harmonization both transmission modes is a largely identical sig nal processing possible in the subscriber stations. This will the same time slot length is used for both modes.

To take advantage of the flexible capacity increase (soft capa city) by assigning additional codes or changes The frequency bands are to be used for the spreading factor broadband and the data shares are with a subscriber or channel-specific spreading code spread.

The receivers for subscriber stations operating in both the TDD as well as in the FDD (frequency division multiplex) should be simplified if the same in both modes che timeslot lengths are used. Thereby several Time slots combined into a frame, the frame length in the TDD and FDD transmission process in one integer relationship.

Embodiments of the invention are based on the enclosed ing drawings explained in more detail.  

Show

Fig. 1 is a block diagram of a mobile radio network,

Fig. 2 is a schematic representation of the data transmission,

Fig. 3 is a schematic representation of the CDMA Übertra off procedure,

Fig. 4 is a block diagram of the transmitter,

Fig. 5 is a block diagram of the receiver,

Fig. 6 is a schematic representation of the transmission in the downward direction, and

Fig. 7 is a schematic representation of the channel structure of the TDD and FDD transmission method.

The radio communication system shown in FIG. 1 corresponds in structure to a known GSM mobile radio network, which consists of a multiplicity of mobile switching centers MSC, which are networked with one another or provide access to a fixed network PSTN. Furthermore, these mobile switching centers MSC are each connected to at least one base station controller BSC. Each base station controller BSC in turn enables a connection to at least one base station BS. Such a base station BS is a radio station, the radio connection via a radio interface to subscriber stations, for. B. can build MS mobile stations.

In Fig. 1, three radio connections for transmission of useful information and signaling information between three mobile stations MS and a base station BS are shown as an example, with one mobile station MS being assigned two data channels DK1 and DK2 and the other mobile stations MS each having a data channel DK3 and DK4. Each data channel DK1..DK4 represents a subscriber signal.

An operation and maintenance center OMC realizes control and maintenance functions for the mobile network or for parts from that. The functionality of this structure is controlled by the radio comm  Communication system used according to the invention, however, it is also transferable to other radio communication systems, in which the invention can be used.

If only the radio interface between the mobile station MS and the base station BS is considered, then this transmission system can be illustrated with FIG. 2. A transmitter transmits modulated basic impulses via a transmission channel to a receiver, which determines system basic impulse responses and further detects the data contained in the modulation in signal processing. Transmitter and receiver can each be realized in the mobile station MS and the base station BS.

According to Fig. 3, several basic impulses are summarized to form a symbol. The basic impulses are applied with different phases for the formation of different symbols. A transmission channel is formed by a sequence of identical symbols, the spreading code. A specific symbol is used for a transmission channel and is therefore channel-specific. A transmission channel is also characterized by a carrier frequency and additionally by a time slot. The information to be transmitted is encoded by modulating the symbols. The data is transmitted by changing the amplitude and / or phase between two successive symbols of a channel. In the case of a digital system, these are at least two agreed exchange options.

For the special case of a CDMA transmission method is a Chip a basic pulse. The two different basic impulses are with BPSK modulation by 180 ° phase change designed in a chip shape. For example, 16 of them Chips combined into a symbol, the choice and Ab follow the chips indicating a spreading code.  

An alternative possibility is e.g. B. 4 chips too summarize a symbol. This corresponds to the minimum Spreading factor in the W-CDMA transmission method. With that Although fewer channels can be distinguished, there are fewer Scanning necessary to differentiate the channels. By the lower symbol clock results in less complexity in the design of the transmitter and receiver.

The transmitter of FIG. 4 is composed of an encoder, a basic pulse generator, a power amplifier and a coupling to the transmission medium. The transmitter generates basic pulses in the basic pulse sequence clock generator, which are passed on to the coupling (antenna or sound generator) via the power amplifier. Depending on the data to be transmitted, the encoder selects which basic pulse is emitted from a supply of total available basic pulses and with which, generally complex modulation factor, this basic pulse is modified.

Different transmission methods differ in Stock of basic impulses. One, several or a larger number of basic pulses can be used. This The basic impulses can be of any length be and are not on the duration of the basic pulse train timed. For basic impulses that are longer than one Period of the basic pulse sequence clock, there is a Superposition of the basic impulses already in the transmitter.

The following signal processing takes place in one in the receiver Device for signal preprocessing: amplification, frequency implementation, analog filtering, A / D conversion and digital fil ture. In particular the overall filter characteristic of the Receiver already changes through the transmission channel modified basic impulses. At the output of the digital Filtering results from a sequence of basic system impulses words in time with the basic pulse sequence. This episode about  stored system basic impulse responses is the signal processing tion and detection fed.

The reception-side signal processing is shown schematically in FIG. 5. It includes the determination of the basic system impulse responses, the determination of the filter coefficients for at least one transversal filter during the evaluation of measurement sequences, the detection of data-bearing parts of the sample values in a one- or multi-stage transversal filter and the decoding of the results of the output of the transversal filter. As an alternative to the transversal filter, digital signal processing can also be used for common detection, as in DE 197 33 860 A1. Refinements for the selection of the basic pulses and the transversal filter can be found in German patent DE 197 47 454 C1. This type of signal detection can be used in both transmission directions.

FIGS. 6 and 7 shows the radio interface between base station BS and mobile station MS in both transmission methods. The transmission in the different frequency bands FB1, FB2, FB3 is synchronized with one another. Here are broadband frequency bands with z. B. B = 1.6 MHz used.

In the TDD transmission method according to FIG. 6, a first frequency band FB1 is used both for the downward direction DL (from the base station BS to the mobile station MS) and for the upward direction UL (from the mobile station MS to the base station BS), a switching point being the transmission direction separates. The TDD transmission method according to Fig. 6 in the downlink DL continuously, ie, not bursty transmitted. A data portion follows a channel measurement sequence ma. The channel measurement sequences ma can be used for channel estimation by all mobile stations MS, during which the data portions are individually assigned to the individual mobile stations MS.

The switchover point is followed by a time interval which is determined by the mobile MS stations arbitrarily as an access channel for a request a resource allocation is used. The length of time intervals corresponds to a time slot in up downward direction. In the upward direction UL comes a burst-like Transmission in time slots is used, one of one Mobile station MS sent radio block each a channel measurement sequence ma in the middle of two data components. Between the radio blocks are transmission breaks as protective distances provided for better separability of the received signals.

In the FDD transmission process, the frequency bands for the two directions of transmission separated. So a second one Frequency band for the downward direction DL and a third Fre quenzband FB3 used for the upward direction UL.

Both transmission methods, see Fig. 7, divide the data to be transmitted in frames for the same length. Alternatively, the frame length of one transmission method can also be a multiple of the other frame length. With both transmission methods, channel measurement sequences ma and data components alternate within a frame fr. In particular, the channel structures in the downward direction DL are coordinated with one another.

In the FDD transmission method, see FIG. 7, the upward and downward direction UL, DL are similar and structured in accordance with the downward direction DL of the TDD transmission method. During a continuous transmission, channel measurement sequences ma and data components alternate cyclically. There are therefore two channel measurement sequences ma per channel for data estimation.

For both transmission methods and both transmission systems the signals of several participants are simultaneously in a frequency band FB1, FB2, FB3 transmitted, one Differentiation is made on the basis of individual spreading codes.  

A CDMA (code division multiple access) Participant separation process used, the simple Adaptation of the data rate of a connection between base station BS and mobile station MS by assigning one or multiple spreading codes or changing the spreading factor possible light.

The similarity of the channel structures in the downward direction DL of TDD and FDD transmission methods simplifies the emp catcher structure of mobile stations MS, both transmission support procedures and a common detection use algorithm. A particularly important part of the emp signal evaluation on the upstream side is the channel estimate. The Channel estimation is used to determine the channel characteristics of the radio to appreciate and model the channel through the interface Choosing individual filter coefficients, which at the data detection to equalize those disturbed in the channel Contributes data. The channel estimate is based on the Channel measurement sequences ma performed, the waveform in the Emp catcher is known.

For the mobile radio system shown in FIG. 1, several neighboring base stations BS emit the same channel measurement sequences ma, which contain the same chip sequence. However, each of these base stations BS, which are synchronized with one another, sends the chip sequence starting with a different code phase. The code phases are equidistant. This makes it possible for the mobile stations MS at the receiving end to simultaneously perform the channel estimation to a plurality of base stations BS by performing a cyclical correlation with the chip sequence. The cyclic correlation creates a measurement window for each base station BS, which enables a separate determination of filter coefficients.

The evaluations of several channel measurement sequences ma interpolated or extrapo for a quick evaluation The channel estimation is especially fast for itself  moving mobile stations MS to improve. From a base station BS, the channel measurement sequences ma with maximum Transmission power and there is no overlay with data components sent to avoid any performance corruption of the channel allow estimate.

In the case of a mixed operation of base stations BS operating in downward direction towards continuous transmission, and other base stations BS that burst in the downward direction in conventional operation send like, are from the total stock possible channel measurement sequences ma different subsets for each Operating modes used.

Claims (11)

1. Method for data transmission in a radio communication system over a radio interface between a base station (BS) and subscriber stations (MS), in which

• - A first frequency band (FB1) is provided for data transmission according to a TDD transmission method, the transmission directions within the first frequency band (FB1) being separated by at least one switchover point, with transmission in the upward direction (UL) discontinuously slitting in times separated by guard intervals is carried out,

characterized in that a transmission is carried out continuously in the downward direction (DL), with data components (da) and channel measurement sequences (ma) alternating in a cyclical sequence. 2. The method according to claim 1, characterized in that that a time interval for an arbitrary access of the Subscriber stations (MS) arranged near the switchover point is. 3. The method according to any one of the preceding claims, characterized, that from a base station (BS) the channel measurement sequences (ma) with maximum transmission power and without overlay with data share (da) are sent. 4. The method according to any one of the preceding claims, characterized, that with a channel estimation in a subscriber station (MS) Interpolated evaluations of several channel measurement sequences (ma) or extrapolated. 5. The method according to any one of the preceding claims, characterized,  that several base stations (BS) have the same channel measurement sequence (ma) use in downward direction, the channel measurement sequence (ma) from the base stations (BS) with different code phases be sent. 6. The method according to claim 5, characterized in that with a channel estimation in a subscriber station (MS) a cyclic correlation to channel estimation of transmissions channels to several base stations (BS) is used. 7. The method according to any one of the preceding claims, characterized, that when detection of simultaneously transmitted data a ge joint detection or transversal filtering with Elimi at least one interference signal is carried out. 8. The method according to any one of the preceding claims, characterized, that a second and third frequency band (FB2, FB3) for Da transmission according to an FDD transmission method can be seen, whereby in all three frequency bands (FB1, FB2, FB3) the same time slot lengths can be used. 9. The method according to claim 8, characterized in that several time slots are combined into a frame the frame lengths in TDD and FDD transmission procedures are in an integer relationship to each other. 10. The method according to any one of the preceding claims, characterized, that the frequency bands (FB1, FB2, FB3) are broadband and the data shares (da) with a participant-specific Spreading code are spread. 11. Radio communication system with over a radio interface, which by a first Frequency band (FB1) according to one of the transmission directions by at least one switchover point separating TDD over transfer procedure is formed, associated participants stations (MS) for discontinuous data transmission in Upward direction (UL) separated by guard spaces Time slots and base stations (BS), characterized, that the base stations (BS) for continuous data transfer are formed in the downward direction (DL), where Data components (da) and channel measurement sequences (ma) in cyclical Alternate episode.