WO2001037442A1 - Method for signal transmission in a radio communication system - Google Patents

Abstract

The invention relates to a radio communication system that uses a TD/CDMA subscriber separation method and whose radio interface is organized according to a TDD method. The signals transmitted uplink from a subscriber station are evaluated by a base station in a channel estimation step. The base station then predistorts the data and a training sequence of a burst to be transmitted to the subscriber station in the downlink direction. The subscriber station chooses a receiving method suitable for the receipt of the data elements on the basis of a channel impulse response of the known training sequence.

Description

description

Process for signal transmission in a radio communication system

The invention relates to a method for signal transmission and a base station and a subscriber station of a radio communication system, in particular a mobile radio system, for carrying out the method according to the invention.

In radio communication systems, information such as, for example, voice, picture information or other data, is generated with the aid of electromagnetic waves via a radio interface between a transmitting and a receiving mobile station, such as a base station or a mobile station for the case of one Mobile radio system. The electromagnetic waves are emitted at carrier frequencies that lie in the frequency band intended for the respective system. In the GSM mobile radio system (Global System for Mobile Communication), the carrier frequencies are in the range of 900 MHz, 1800 MHz and 1900 MHz. Carrier frequencies in the range of approx. 2000 MHz are provided for future mobile radio systems with CDMA and TD / CDMA transmission methods via the radio interface, such as the UMTS (Universal Mobile Telecommunication System) or other 3rd generation systems. For the UMTS mobile radio system mentioned, a distinction is made between a so-called FDD mode (Frequency Division Duplex) and a TDD mode (Time Division Duplex). The TDD mode is particularly distinguished by the fact that a common frequency band is used both for signal transmission in the upward direction (UL - Uplmk) and in the downward direction (DL - Downlmk), while the FDD mode for the transmission directions uses a respective frequency band uses. _Fo r the TDD mode is distortion in the document by Bosch "Joint Pre: a proposal to allow for low cost UMTS TDD mode terminals *, Tdoc SMG2 UMTS LI 82/98, ETSI SMG2 UMTS Ll, Pa ^¬ ris, 28 April 1998, proposed to use a method for joint predistortion (JP). This method is based on the principle that instead of subscriber-side equalization of signals sent in the downward direction, the complexity of the equalization is shifted to the base station, in which the data of radio blocks to be transmitted are predistorted. On the basis of an assumed reciprocity of the channel properties during the transmission in the upward direction and the downward direction - the transmission takes place temporally separated in a common frequency band in the TDD mode - the signals m of the base station are predistorted in such a way that the subscriber station experiences ideal channel properties. With this method, both the so-called intersymbol interference (ISI - Inter Symbol Interference) and the interference caused by multiple access (MAI - Multiple Access Interference) can be removed from the base station.

The advantage of the JP method over the known Jomt detection method (JD - Joint Detection) or the multi-fmger rake receiver (MRF - Multi Rake Finger) for detection lies in the significantly lower complexity of the reception algorithms the fact that, for example, an em finger rake receiver (SRF - single rake finger) is sufficient for data detection, which enables energy savings in the subscriber station. Disadvantageously, however, this method can only be used up to a certain maximum speed - assuming a maximum of 40 km / h - of the subscriber station, since at higher speeds the channel properties m the time interval between the signal transmission in the upward direction and the downward direction or between several sig- nal transmissions can change greatly in the upward direction. He ^¬ follows such a strong change in the channel properties, the JP method due to a faulty angenomme ^¬ nen reciprocity can not sufficiently fast nachfuhren predistortion and there is a marked deterioration in Empfangsqualltat in the subscriber station.

For this reason, it is proposed that, in an over ^¬ falls below a certain speed of the subscriber station, which is characterized by changing channel characteristics, the JP-process is switched off and the subscriber station following the reception of the data by means of a Jomt Detection or more -Fmger rake receiver performs. The use of or not the JP method must be signaled to the subscriber station by the base station via higher transmission layers in accordance with the standardized ISO-OSI layer model. In addition to a certain delay in signaling, such a signaling - a change in the reception method should be possible on a time frame basis - the problem that the subscriber station may no longer be able to detect the signals sent to it, since it continues to have ideal channel conditions goes without necessary equalization, and the connection breaks.

The invention is based on the object of specifying a method, a base station and a subscriber station of a radio communication system which enable efficient use of the described Jomt predistortion method. This object is achieved by the method, the base station and by the subscriber station in accordance with the features of the independent claims. Further developments of the invention can be found in the subclaims. Erfmdungsgemaß is based on a radio communication system, which uses a TD / CDMA subscriber and the radio interface is ized in accordance with a TDD method orga ^¬, from a base station carried out a channel estimation of m uplink direction from a subscriber station transmitted signals. The base station then carries out a predistortion of data and a training sequence of a radio block to be transmitted in the downward direction to the subscriber station. Depending on a channel impulse response of the known training sequence, the receiving station selects a receiving method suitable for receiving the data.

The implementation according to the invention advantageously enables the subscriber station to make an independent decision about the reception algorithm to be used on the basis of the channel impulse response determined, without this having to be signaled to it via higher transmission layers, as in the prior art described. This ensures a consistently high transmission quality. The autonomous decision-making ability is based on knowledge of the training sequence, which is predistorted by the base station m in the same way as the data of the radio block, whereas in the prior art only predistortion of the data was provided, and from which the subscriber station performed an m of the base station Can detect predistortion.

In a channel estimator of the subscriber station, the channel pulse response is determined from the received training sequence. With a precise predistortion by the base station, ie with an assumed reciprocity between the transmission properties of the radio interface in the up and down direction, an undistorted training sequence appears at the receiving device of the subscriber station. The subsequent correlation of this undistorted training sequence with the ideal training sequence leads to a channel impulse response corresponding to a delta impulse. If the subscriber station recognizes that the real transmission channel has such an impulse response, it can advantageously receive the data of the radio block, for example by means of an Ein-Fmger rake receiver. As explained in the introduction, this type of receiver enables a lower energy consumption of the subscriber station due to a lower computational complexity compared to a Jomt detection or multi-finger rake receiver, which leads to an advantageous extension of the operating time, particularly in the case of mobile subscriber stations. However, if the subscriber station recognizes that the channel impulse response determined does not correspond to a delta impulse, for example if the base station does not carry out predistortion, or if it does so, the training sequence appears distorted at the receiving device, then the Jomt Detection or Multi-Fmger rake receiver selected to receive the data.

According to further developments of the inventions, the base station carries out predistortion, for example in accordance with the Jo t predistortion method described in the introduction, depending on a determined variation in the channel properties. The properties which change from time frame to time frame are determined by a respective channel estimate of the upward direction of the signals sent by the subscriber station. The Jomt predistortion method is advantageously carried out by the base station if, for example, several successive channel estimates have shown that the subscriber station (s) have a respective time slot

Timeframe not moving or moving at a slow speed. If this condition is met, the transfer properties for the upward direction can be used to determine the transfer properties for the downward direction. tion can be closed. There is a reciprocity between the two directions of transmission.

In the Jomt predistortion method, the training sequence known to the subscriber station and the unknown data are distorted in the same way in order to compensate for the real channel impulse response. The quasi series connection of a predistortion and a distorting real transmission channel results in an ideal transmission system.

The method according to the invention and the components of the radio communication system which interact with it will now be explained in more detail with the aid of drawings. Show

1 shows a block diagram of a radio communication system, in particular a mobile radio system,

2 shows an exemplary schematic representation of the frame structure of the radio interface and the structure of a radio block,

3 shows a block diagram of a transmission device,

4 shows a block diagram of a receiving device, and

5 shows a flowchart of the method according to the invention.

1 shows part of a mobile radio system as an example of the structure of a radio communication system. Each mobile radio system consists of a large number of mobile switching centers MSC (Mobile Switchmg Center), which belong to a switching network (Switchmg Subsystem) and are networked with one another or provide access to a fixed network PSTN, and each with one or more Mobile switching centers MSC connected base station systems iαs BΞS (Base Station Subsystem). Em base station system BSS in turn comprises at least one RNC to (Radio Network _C ontroller) for allocating radio resources as well as at least one respectively associated base station NB (Node B).

A base station NB can establish and maintain connections to subscriber stations UE (user equipment) via a radio interface. At least one radio cell Z is formed by each base station NB. The size of the radio cell Z is generally determined by the range of an organization channel (BCCH - Broadcast Control Channel), which is transmitted by the base stations NB with a respectively higher and constant transmission power. In the case of sectorization or hierarchical cell structures, a plurality of radio cells Z can also be supplied per base station NB.

The example in FIG. 1 shows a subscriber station UE which is located in the radio cell Z of a base station NB and moves at a speed V. The subscriber station UE has set up a communication link to the base station NB, on which a selected service is transmitted in the upward UL and downward direction DL. The communication connection is separated by one or more spreading codes assigned to the subscriber station UE from communication connections established in parallel in the radio cell Z, the subscriber station UE, for example, all spreading codes currently assigned in each case to the radio cell Z for receiving the signals of the own communication connection in accordance with the known jo t Detection method uses.

An exemplary frame structure of the radio interface as it is in the TDD mode of the future mobile radio system of the third generation UMTS (Universal Mobile Telecommunications System) as well as a modified form of the future Chinese TD-SCDMA mobile radio system is shown in FIG 2. According to a TDMA component, a division of a broadband frequency band, for example the bandwidth B = 5 MHz, into several time slots ts, for example 16 time slots ts0 to tsl5, is provided. Each time slot ts within the frequency band B forms a frequency channel. Within a broadband frequency band B, the successive time slots ts are structured according to a frame structure. In this way, 16 time slots ts0 to tsl5 are combined to form a time frame fr. Several subsequent time frames for result in a multiple frame.

When a TDD transmission method is used, part of the time slots tsO to tsl5 in the upward direction UL and part of the time slots tsO to tsl5 in the downward direction DL are used, the transmission in the upward direction UL taking place, for example, before the transmission in the downward direction DL. In between is a changeover point SP (SP - Switch Point), which can be flexibly positioned for the up and down direction according to the respective need for transmission channels. Due to the variable allocation of the time slots ts for upward or downward direction UL, DL, diverse asymmetrical resource allocations can be made.

Information of several connections m radio blocks fb are transmitted within the time slots ts. The data d are spread individually for each connection with a fem structure, a spreading code c, so that on the receiving side a number of connections can be separated by this CDMA component (code division multiple access). From the combination of a frequency channel and a spreading code c, a transmission channel is defined which can be used for the transmission of signaling and useful information. The spread of em- causing individual symbols of the data d in that the duration T _{p c} ι be transferred within the Sym ^¬ bold except T _sym Q chips. The

Q chips form the connection-specific spreading code c. A radio-specific training sequence tseql ... is also arranged in the radio blocks fb and is used for channel estimation at the receiving end. Furthermore, a protection time gp is provided within the time slot ts to compensate for different signal tents of the connections of successive time slots ts.

The examples described below to explain the method according to the invention are not limited to the radio interface structure shown by way of example in accordance with FIG. 2. In the same way, the method can advantageously the aforementioned Chinese TD-SCDMA mobile radio system (Time Division Synchronized Code Division Multiple Access), in which the signal transmission in the upward direction UL is synchronized, and its structure of the radio interface a few points from the explained TDD mode UMTS systems deviate, can be realized.

A transmitter structure according to FIG. 3 is used in a CDMA transmission method. K data streams are to be transmitted via the radio interface. Channel coding, scrambling (mterleavmg), modulation and spreading (spreadmg) of the data are carried out. The spreading is carried out with individual spreading codes cl..cK, which allow a distinction to be made between subscriber signals within the signal mixture. The individual subscriber signals are then summed up and formed with the sum signal in a radio block. The radio block formation relates primarily to a transmission system with "burst start" transmission. For continuous transmission, as in W-CDMA mode, the data of a time slot are compiled within the radio block formation. Thereupon the signal becomes one Filtered chip pulse filter and m D / A converter m em converted analog signal, which can be amplified and radiated via antennas AT.

The corresponding structure of a receiving device can be seen from FIG. 4. After the signals have been received at the receiving radio station via an antenna, then amplified and converted to baseband, the received signal is sampled and A / D converted so that the received signal can be fed to a digital low-pass filter. The digitized signal is now fed in parallel to a channel estimator KS and a detection device DE. It is assumed for the following consideration that the received signal is in the form of a received matrix e, where

e = A * d + n applies.

A describes a system matrix, d specifies the data to be detected in m matrix form and n is a matrix containing the noise component.

In the channel estimator KS, training sequences which are distorted in the received signal are compared with undistorted training sequences present in the receiver and pulse responses are determined from the comparison, which describe the transmission channel individually for each participant. The system matrix A is set up with the aid of the channel impulse responses. The system matrix A contains values related to the individual channel impulse response words, which are also referred to as a combined channel impulse response. The combined channel impulse response is created by folding the spreading code c with the associated channel impulse response individually for each subscriber signal. In the case of a rake receiver, a system matrix A is also used mathematically. Here are the m Kanalim ^¬ impulse responses only certain corresponding fingers of the rake receiver's considered paths. This can also be generalized to multi-user detection based on the rake receiver.

The structure of the transmitting and receiving device can be implemented in the same way in the subscriber stations UE, only one data stream branch being taken into account.

FIG. 5 shows an example of a sequence diagram to explain the method according to the invention. When a communication connection is established, the subscriber station UE sends radio blocks fb in accordance with the assigned time slot ts within a time frame for signal transmission. As described above, the radio blocks fb consist of data d and at least one training sequence tseq. This training sequence tseq is used in the base station NB for channel estimation, the channel estimation for

Replication of the real transmission conditions on the radio interface between the subscriber station UE and the base station NB is used. By evaluating several successive channel estimates, the base station NB can determine a variation in the transmission properties, the transmission properties m generally changing depending on the speed V of the subscriber station UE, or drawing conclusions about a specific speed V of the subscriber station UE from a change in the properties can be.

If the base station NB determines that the transmission properties change only slightly, ie the subscriber station UE only moves at a low speed V or does not move at all, then it leads for the signal transmission in the downward direction. device DL to the subscriber station UE by predistortion in accordance with a Jomt predistortion method JP. However, if the specific transmission properties vary greatly, for example due to a high speed V of the subscriber station UE, the base station NB no longer carries out predistortion, since precise prediction of the predistortion is no longer possible and no “ideal channel” at the location of the subscriber station UE can be ensured. This also takes place if only one of the subscriber stations supplied by the base station NB causes a strong variation.

The decision as to whether a predistortion is carried out or not can be made, for example, by comparing the determined variation of the transmission properties with a specific threshold value, with exceeding the threshold value for switching off or falling below the threshold value for switching on the Jo t-Predi stortion procedure JP leads. However, switching off the JP method from a certain variation is not a condition for the advantageous effect of the method. For example, switching off can only take place when the base station NB determines that an incorrectly predistorted channel has a more unfavorable effect than the non-predistorted channel on the reception quality of the subscriber station UE.

In the subscriber station UE, the a priori known training sequence tseq m the radio blocks fb is used for channel estimation in the same way. If the Jomt predistortion method JP is carried out for the two transmission directions UL, DL of the base station NB on the basis of a determined reciprocity of the transmission properties, the undistorted training sequence tseq appears on the receiving device of the subscriber station UE, since the predistortion was calculated in this way using the JP method that the channel impulse response becomes a delta pulse. Is this the If so, an so-called ideal channel is assumed and an Em-Fmger rake receiver SRF with the known advantages is used for the detection of the data d of the radio block fb. If, on the other hand, the channel estimate m of the subscriber station results in a distortion of the training sequence tseq, the subscriber station UE concludes that a multi-F ger rake receiver MRF or an Jomt detection receiver JD is required for receiving the data d. This can also be the case if the JP method is still carried out by the base station NB, but due to an increased speed V or transmission disturbances there are nevertheless distortions and there is no longer an ideal channel. If the channel impulse response subsequently approaches a delta impulse, the subscriber station UE uses an Em-Fmger rake receiver SRF as described.

Claims

claims

1. Method for signal transmission in a radio communication system which uses the TD / CDMA subscriber separation method, the signal transmission being carried out on a radio interface between a base station (NB) and at least one subscriber station (UE) in accordance with a TDD method, in which a channel estimate of signals sent by the base station (NB) in the uplink direction (UL) from the subscriber station (UE) and a predistortion (JP) of data (d) and a training sequence (tseq) of a downstream direction (DL) to the at least one subscriber station (UE) to be transmitted radio blocks (fb), and by the at least one subscriber station (UE) depending on a channel impulse response of the known training sequence (tseq) em suitable reception method (SRF) for receiving the data (d), JD, MRF) is selected.

2. The method according to claim 1, in which the at least one subscriber station (UE) receives J emt detection method (JD), em fmger rake method (SRF) or em multi fmger rake method ( MRF) is used.

3. The method according to any preceding claim, in which a predistortion (JP) is carried out by the base station (NB) depending on a variation in the channel properties determined by means of the channel estimation or not.

4. The method according to any preceding claim, in which the base station (NB), depending on a determined speed (V) of the subscriber station (UE), carries out the predistortion (JP) or not.

5. The method according to any preceding claim is carried out in which from the base station (NB) for predistortion em Jo t-Predi- stortion method (JP), said radio ^¬ blocks (fb) of all supplied by the base station (NB) ak - Active subscriber stations (UE) are predistorted together.

6. Base station (NB) of a radio communication system that uses the TD / CDMA subscriber separation method and in which a signal transmission takes place on a radio interface between the base stations (NB) and at least one subscriber station (UE) according to a TDD method, with at least one Channel estimator (KS) for determining transmission properties of the radio interface based on signals sent in the upward direction (UL) of at least one subscriber station (UE), and at least one modulation device (modulator) for predistortion (JP) of data (d) and a training sequence ( tseq) of a radio block (fb) to be transmitted subsequently in the downward direction (DL) to the at least one subscriber station (UE).

7. subscriber station (UE) of a radio communication system which uses the TD / CDMA subscriber separation method and in which a signal transmission takes place on a radio interface between a base station (NB) and at least one subscriber station (UE) according to a TDD method, with at least one channel estimator for determining a channel impulse response of a known training sequence (tseq) predistorted and transmitted by the base station (NB) in the downward direction (DL), a radio block (fb), and one

Evaluation device for selecting a suitable reception method (SRF, JD, MRF) for receiving data (d) in the radio block (fb) depending on the channel impulse response determined.