DE19917334A1 - Channel estimation method for TD-CDMA mobile radio system - Google Patents

Abstract

The method involves using reception values of several bursts for estimating a single channel impulse response, if the time (Tauf) in which the consecutive data bursts are transmitted, is substantial smaller than the coherent time (Tk). Preferably, the condition Tauf Tk applies to subscriber with low speed. The midamble necessary for the channel estimation is divided into several sub-midambles. Each midamble is transmitted in a burst of a sequence of bursts so that the overall midamble is provided from the sub-midambles of consecutive bursts.

Description

In TDMA-based CDMA mobile radio systems (TDMA = Time Division Multiple Access, CDMA = Code Division Multiple Access) a channel estimate is required to carry out the data estimation. The channel estimation in the TDMA-based systems is based on a training sequence, which is generally referred to as the midamble, the midamble being arranged between two data blocks. The unit consisting of the midamble and the two data blocks is called a burst. He gives himself from Bernd Steiner: "A contribution to the mobile radio channel estimation with special consideration of synchronous CDMA mobile radio systems with joint detection", progress reports VDI, row 10, no. 337, Dusseldorf: VDI-Verlag 1995, that the length L _{m of} the midamble in TD-CDMA mobile radio systems, due to the algorithm used for channel estimation, directly from the number of active subscribers K and the maximum expected length W of the channel impulse response due to the approximation

L _m ≈ W (K +1)

is determined. Thus, the length L _{m of} the midamble is a limiting factor for the number of active participants that can be present in the uplink per burst. If techniques such as "voice activity" or adaptive data rates are to be used, it may even be necessary to support more participants than are actually active per burst, in other words, to include them in the channel estimation.

Furthermore, intelligent antennas in the base station, the is called antennas, for example, selectively in the direction of Cellular subscriber act, are used in the down link also requires participant-specific midambles, see above  that here too the midambell length is a limiting factor becomes.

Furthermore, it is in TD-CDMA mobile radio systems with a Fre quenz-reuse factor of r = 1 possibly desirable, inter Cell interference signals from neighboring cells in the data selec tion to be included. For this it is necessary to connect to the channels Neighboring stations or the mobile stations of the neighboring cells to appreciate.

But this is only possible if the Mitt is long enough are available. Hence the unrelated peaceful situation that the remaining, for the data transfer available portion of the burst the more decreases the more channels need to be estimated. Therefore Many channels should be estimated on the one hand, but others on the other hand, only as small a portion of the burst as possible should the midamble will be sacrificed. This problem is prince not only with the channel estimation method mentioned above the above publication, but all Estimation method. A sufficiently accurate estimate To be able to achieve is therefore a minimum number of measured values required from the received midamble.

So far, this conflict has not been satisfactorily resolved become. Rather, there has been a compromise between Mittam length and the data transmission available Burst component found. Usually the midambell length is like this dimensioned that at least as many channels are estimated like CDMA codes in a cell can be detected at the same time are animal. The number of CDMA- Codes is essentially used by the spreading factor and determines the intercell interference. Therefore it is a custom compromise between mid-length and number estimable channels only possible if the spreading factor is not too big, in other words, if we are relatively few participants the data transmission capacity of a burst  divide. This requires a mini that is too high for many applications male data rate and offers little scope for the application of the above-mentioned capacity-increasing measures such as voice Activity, adaptive data rates, antenna diversity and Elimi nation of intercell interference.

The invention is therefore based on the object of a method and to provide a device with which an estimate can be made ner increased number of channels is possible without the proportion of Bursts for the midamble is enlarged.

The task is characterized by the features of the independent claims che 1 and 10 solved. Preferred embodiments of the invention are the subject of the subclaims.

The minimum time interval between two channel impulse responses within which the channel impulse responses can be regarded as uncorrelated is defined as the coherence time T _K. Furthermore, the coherence time T _{K is} inversely proportional to the speed of a participant.

Now, the channel impulse responses of successive bursts almost the same, that is, the period _T, in which the transfer consecutive data bursts is materiality Lich smaller than the above-defined coherence time T _K, so who the estimation of a single channel impulse response for the channel estimation usable reception values of several bursts are used. Participants with low speed in particular meet the condition

T _on «T _K.

Midambles can preferably be briefly transmitted within the burst, the channel estimate then determining a current channel impulse response from the received values e (x) of several successive bursts x originating from the midambles. The received values of so many bursts must be taken into account in the channel estimation that the required quality for the channel estimation is achieved. This procedure is possible only if the channel impulse responses within the period in which the required reception values e (x), x = 1.. .X are received, are largely identical, in other words the condition T _on «T _{K is} fulfilled. Furthermore, the lower the speed of a mobile station, the shorter the midamble, since this increases the coherence time T _K and the higher the data rate can be achieved.

Due to the principle of sending the midamble piece by piece consequently the number of participants will be increased. If you leave the length the midamble within the bursts is the same and in interprets them as sections of a long midamble, so it is possible to accommodate significantly more participants. Therefore, the problem can usually be caused by the channel estimate hard limited number of subscribers in TD-CDMA-Mobil radio systems can be considered as solved.

Furthermore, given the validity of the estimate T _on «T _K within a burst, it is not absolutely necessary to use middle ambles, but the use of preambles is generally possible. Advantageously, preambles due to their property that they are not disturbed by the interference of previous symbols can be chosen shorter than with tambeln, which increases the data rate, for example. If the preamble and the midamble are of the same length, then the use of preambles enables a higher number of participants.

Preferred embodiments of the invention are as follows described with reference to the drawings.

Fig. 1 shows the division of a midamble into several shorter midambles, and

Fig. 2 shows the use of periodic midamble codes.

Fig. 1 shows the division of a Mittambel m into several Mitt ambeln m (x), where x runs from 1 to X. By transmitting the midamble m in sections in successive bursts, the midamble of a burst is shortened, so that the number of channels that can be estimated is increased due to the short midamble.

The midamble m in the case described here by way of example consists of X = 5 blocks of length W. The received signal originating only from the not yet divided midamble m is calculated for any subscriber k

The total received signal originating from the middle tones of the participants results from the superimposition of the signals of the K participants

Furthermore, the reception sequence e _m is shorter by W elements than the midamble, since reception values with interference from the data blocks cannot be used for channel estimation.

So that the same algorithm can be used for channel estimation after splitting the midamble over several bursts as before, which is based on the reception sequence e _m of length KW, the signal e _m must also be generated by the transmission of the midamble in sections. In the example in FIG. 1, the signal e _{m is} composed of four sub-signals e _m = [ e _m (1). . . e _m (4)] together if the midamble m is distributed over X = 4 bursts. The received values of e _m (1) result from the transmission sequence of the midamble part m (1) and, since the channel impulse response has the length W, from the W-1 previous samples from the block m (0). The received values of e _m (2) result from the transmission sequence m (2) and, since the channel impulse response has the length W, from the W-1 previous samples from block m (1). The same applies to the reception values e _m (3) and e _m (4).

After the transmission of the four bursts, as shown in FIG. 1, the identical signal e _m = [ e _m (1) can be obtained from the four reception sequences. . . e _m (4)] can be composed if the channel impulse response is constant. The channel estimation can be carried out in a cost-effective manner according to a method described in the above-mentioned article.

The estimation of the channel impulse response can be carried out in the steady state after the reception of each burst and thus of each section e _m (x), if, for example, an older e _m (1) is replaced by a just received section of the same name. The result of the channel estimation is therefore adaptively tracked to the slowly changing channel.

Fig. 2 shows how blocks of the midamble emerge from a periodic midamble code described in the above publication. If the supported subscriber number K is a multiple of the number X of bursts to which the midamble is divided, the midamble distribution at the channel estimator manifests itself as a cyclical interchanging of the midambles used by the subscribers. Exactly the same channel estimator can be used for each burst, which uses the midamble reception signals of the last X bursts. The estimated value h of the channel impulse responses results from the constant, right-circulating matrix G ^-1 , which is dependent only on the midamble codes used

h = G ^-1 e _m (3)

Since only a part of the reception sequence e _{m is} newly acquired per burst, it is not absolutely necessary to carry out a complete channel estimation for each burst. Since this is a linear estimation algorithm, one can instead of sen from the difference between old and new reception sequence e _m directly the difference between old and new estimation of the channel impulse response and determine the estimation result h tualisieren ak.

In the example in FIG. 2, X = K = 4. The periodic basic code PGC is divided into four components, each beginning with m ₁ , m _{W + 1} , m _{2W + 1} , and m _{3W + 1} . The periodic basic code PGC ends with the character m _KW . Between the participants T1, T2, T3 and T4, the said basic code PGC is always periodically shifted by one block, with the participant T1 sending the components m ₁ and m _{W + 1} in the midamble M1, while the participant T2 is the components m _{W + 1} and m _{2W + 1} , the subscriber T3 sends the components m _{2W + 1} and m _{3W + 1} and the subscriber T4 the components m _{2W + 1} and m ₁ in this order. Correspondingly, the 8 components of the periodic basic code PGC which are arranged above it in FIG. 2 are sent in the middle messages M2 to M4. The midamble M1 is sent in the first burst B1, while the midambles M2 to M4 are sent in the corresponding subsequent second to fourth bursts. In FIG. 2, the components of the first midamble sent in the first burst B1 M1 is in the partial image shown to the right below.

Claims (10)

1. Method for channel estimation in TD-CDMA-Mobilfunksyste men, characterized in that for the estimation of a single channel impulse response h, the reception values e _m (x), x = 1, which can be used for the channel estimation. . , X be used several bursts., If the period _T, in which the successive data bursts are transmitted is significantly smaller than the coherence time T _K. 2. The method according to claim 1, characterized in that the condition T applies _to «T _K for participants with low speed. 3. The method according to any one of the preceding claims, characterized in that the midamble m necessary for channel estimation to several partial midambles m (x) with x = 1. . ., X is divided, each partial midamble m (x) being transmitted in a burst of a sequence of X bursts, so that the total midamble m is composed of the partial midambles m (x) of the successive bursts. 4. The method according to any one of the preceding claims, characterized in that the partial reception values e _m (x), x = 1 ,. . ., X of the received signal e _m so many bursts are taken into account in the channel estimation that the required quality for channel estimation is achieved. 5. The method according to any one of the preceding claims, characterized in that the estimation of the channel impulse response h in the steady state after the beginning of each burst and each section e _m (x) are carried out. 6. The method according to any one of the preceding claims, characterized in that instead of the middle ambles Preambles can be used. 7. The method according to any one of the preceding claims, characterized in that the channel is guided adaptively by a temporally older section e _m (x) of the received signal e _{m of} a burst is replaced by the just received section. 8. The method according to any one of the preceding claims, characterized in that to generate the Mitt the participants use a periodic basic code becomes. 9. The method according to claim 8, characterized in net that the Mittambel distribution on the channel estimator as Cyclical swapping of the ones used by the participants Mittambeln expresses when the supported number of participants K is a multiple of the X shares of the bursts on which the Dividing the middle furniture. 10. TD-CDMA mobile radio system using the method according to one of the preceding claims.