EP0931389A1

EP0931389A1 - Preamble for the assessment of channel impulse response in a antenna diversity system

Info

Publication number: EP0931389A1
Application number: EP96927497A
Authority: EP
Inventors: Weilin Liu
Original assignee: Ascom Systec AG
Current assignee: Ascom Systec AG
Priority date: 1996-09-04
Filing date: 1996-09-04
Publication date: 1999-07-28
Also published as: JP2001504648A; AU6730596A; CA2264789A1; AU726748B2; WO1998010531A1

Abstract

A preamble in a digital signal transmission system characterized by several different bit sequences (m1-m5) which are suited for packet synchronization and channel assessment. M-sequences with a length of, for instance, 31 bits are used advantageously and repeated three times. This enables antenna selection in a receiver. In addition the frequency offset can be determined on the basis of two sequences (54, 55) captured within a specific time period.

Description

PREAMBLE FOR ESTIMATING THE CHANNEL IMPULSE RESPONSE IN AN ANTENNA DIVERSITY SYSTEM

Technical field

The invention relates to a preamble in a digital signal transmission system. The invention further relates to a transmitter, a receiver and a method for a digital signal transmission system with a preamble of the type mentioned State of the art

In the case of block-wise data transmission (burst signaling), it is known to use the preamble, which is required for clock and packet synchronization and is at the beginning of the block, to carry out an antenna selection for switching diversity. During the reception of the preamble, the signal strength becomes strong measured for the existing antennas in order to then use the antenna signal with the greatest power for data detection

Such a receiver structure is proposed, for example, in the publication IEEE VTC-95, pp 514-519 "Evaluation of an advanced receiver concept for DECT", PE Mogensen et al for DECT, the conditions of use of this system (DECT) being defined in such a way that none Intersymbol interference (but at most fading) can occur

ETS 300 652 (ETSI 1995) defines the technical characteristics of a high-performance wireless local area network (HIPERLAN). HIPERLAN is a short-range communication subsystem with a high data rate, in which intersymbol interference typically occurs

Presentation of the invention

The object of the invention is to provide a preamble which is suitable not only for clock and packet synchronization, but also for antenna diversity and preferably frequency offset estimation. Furthermore, the preamble should also be able to be used without problems in an environment with intersymbol interference

The solution to the task is defined by the features of claim 1. The signal according to the invention thus contains several different bit sequences, whereby each of them is suitable for clock and packet synchronization as well as for channel estimation

In contrast to known systems, it is not a preamble that as a whole has an optimal autocorrelation property, but one that consists of several short sequences that are optimized for a specific purpose.Each of these sequences has a good autocorrelation.This enables one to be used successfully realize sequential antenna selection (sequential antenna diversity)

According to a preferred embodiment, the bit sequences are so-called m-sequences (ie maximum-length sequences, such as can be generated, for example, by suitable feedback-coupled shift registers). A sequence length suitable for the HIPERLAN standard is, for example, m = 31 further shorter (eg m = 15) or longer (eg m = 63) sequences can be used. Instead of m-sequences, the synchronization bit patterns known from the GSM standard can also be used

Each of the sequences is preferably repeated several times. This has the advantage that there is great flexibility in tapping the sequences. It then does not matter which bit is used to start the scanning, as long as the boundary between two different sequences is not exceeded A 3-fold repetition, for example, gives the receiver circuit enough time to select and evaluate a complete bit pattern of the m-sequence. It is of course not imperative that there be an integer repetition of the sequences. It can also be terminated prematurely (e.g. after a 1! Or 2 Y∑-fold repetition to the next sequence, if a standard specifies a certain length of the preamble (e.g. 450 bits for HIPERLAN), then the required can be reached Number of bits can be aborted It is not imperative that all sequences be repeated the same number of times. The number of repetitions can depend on the total length of the preamble available and the purpose or function of a particular sequence

A receiver for evaluating the signal preamble according to the invention has several (ie at least two), in particular three, different antennas. These can be physically completely separated from one another or structurally partially connected. For example, there are diversity antenna arrangements in which the minimum distance λ / 2 can be fallen short of

Furthermore, a circuit is provided in the receiver which determines the best antenna signal. For this purpose, the channel impulse response for each antenna is estimated so that, for example, the antenna signal with the shortest impulse response can be used for data detection. A short impulse response has the advantage that for data detection too You can work with less complex equalizers. Alternatively or additionally, the total energy contained in the taps of the shock response can be taken into account

Depending on the type of subsequent data processing, the sequences of the preamble can also be evaluated with a suitable frequency offset estimate.This can be done, for example, in combination with an estimate of the channel burst response.For the frequency offset estimate determined on the basis of channel burst responses, it is essential that at least two shock responses in one predetermined time interval can be estimated

The preamble according to the invention can be generated on the transmitter side, for example, by reading out the predetermined bit pattern from a read-only memory (ROM, EPROM, etc.). When using m-sequences, a plurality of linearly feedback-shift registers (LFSR = linear feedback shift register) can be provided, one after the other by a Switches are selected Repeating an m-sequence results automatically when the end of a bit period is reached and the shift register is clocked further

The processing of a preamble according to the invention in the receiver proceeds as follows

First of all, the various antenna signals are evaluated one after the other by scanning a complete m-sequence and estimating the channel impulse response

Then the antenna with the best reception is selected for further signal processing - by setting a switch

The following estimation of the shock response of the selected antenna and the frequency offset still takes place within the preamble. The result of this step is used as the basis for the detection of the following data

The repeated estimation of the channel impulse response (namely in the context of antenna selection and frequency offset estimation) of the above embodiment is related to the fact that the preferred frequency offset estimation requires 2 channel estimates at a fixed time interval. Furthermore, the estimation carried out for the antenna selection needs less accuracy to be the one that is subsequently used for data detection

From the following detailed description and the entirety of the claims, further advantageous embodiments and combinations of features of the invention result

Brief description of the drawings

The drawings used to explain the exemplary embodiment show 1 shows a schematic representation of a preamble according to the invention,

2 shows a block diagram of a receiver circuit for processing the preamble according to the invention

3 block diagram of a transmitter circuit arrangement for generating a preamble according to the invention

Ways of Carrying Out the Invention

1 shows a preferred exemplary embodiment of the invention. The (system-specifically defined) preamble is shown, which is followed by a data part (which contains the useful data) which is not described here in greater detail. It consists of 5 sections a1 to a5. Each of these is repeated three times by an m - Sequence m1 to m5 formed. The length of the m-sequences is, for example, 31 bits. This results in a section length of 93 bits and a total length of 465 bits. For use at HIPERLAN, where the preamble by definition has a length of 450 bits, the last 15 bits of the last m-sequence m5 are omitted

A different maximum length sequence is present in each section a1 to a5. The penodicity of the entire sequence is minimal. The following sequence may be mentioned as an example (representation in the form of the generating polynomials).

m1 (x) = x ⁵ + x ² +1 m2 (x) = x ⁵ + x ⁴ + x ³ + x ² + 1 m3 (x) = x ⁵ + x ⁴ + x ² + x + 1 m4 (x ) = x ⁵ + x ³ + 1 m5 (x) = x ⁵ + x ³ + x ² + x + 1 The preamble according to FIG. 1 is tapped in the receiver (which of course must know the m sequences m1 to m5 and the entire format), for example as follows:

In sections a1 to a3, a sequence S1 to S3 of length 31 (= length of the m-sequences) is tapped, with a switchover from one antenna to the next between these sequences. Since the m-sequences are repeated three times in each section a1 to a3, one is not bound to start scanning at a point in time specified by the preamble. Rather, it is sufficient to tap the predetermined number of bits somewhere within a section. For example, the first sequence S1 starts at bit 17, the second at bit 108 and the third at bit 199.

The evaluation of these three sequences S1 to S3 leads to the selection of the antenna with the best reception. For these, the channel surge response and the frequency offset are estimated using the sequences S4 and S5. The distance between the latter sequences S4 and S5 is chosen so that good frequency offset estimates are achieved. (It is e.g. 100 bits.)

2 schematically shows a block diagram of a receiver. This has, for example, 3 antennas 1, 2, 3. A switch 4 can be used to switch between the different antennas 1, 2, 3. A subsequent switch 5 directs the data stream either to a channel estimator 6, an estimator 8 for the combined estimation of channel impulse response and frequency offset, or a detector 9.

The antenna is selected on a first level. The switch 4 is successively set from one antenna to the next, an entire m-sequence being tapped (sequences S1 to S3). The channel taps 6 are used to determine the strongest taps for each antenna 1, 2, 3. The antenna selector 7 then selects the antenna with the best transmission quality. As a result, the switch 4 is set accordingly and retained for the subsequent data processing. The criterion for the selection of the antenna is, for example, the power contained in the taps determined and / or the (small) number of echoes

Once the antenna selection has been completed, the switch 5 is placed on the scraper 8 as part of a second processing stage. This picks up the two sequences S4 and S5 in order to carry out a (preferably combined) estimate of the channel impulse response of the selected antenna and the frequency offset. The result of this Estimation is - at a third stage - actually used in the detector 9 for the detection of the data supplied to it by correspondingly switching the switch 5 (which follow the preamble)

The implementation on the transmitter side of the signal preamble shown in FIG. 1 can be carried out using circuit elements known per se. FIG. 3 shows an example of a block diagram of a possible transmitter-side circuit. The 5 different m-sequences are generated with 5 linear feedback-shift registers 10 1 to 10 5 (the corresponding polynomial -Display was given further above) With a switch 11, the m-sequences are selected one after the other and output for signal modulation. The switch position is maintained just long enough that the required number of repetitions is output

If the preamble is complete, the switch 13 is switched to the data encoder 12 in order to transmit the useful data

Instead of linear feedback shift registers, a read-only memory can also be used. This would then contain the complete bit pattern of the preamble

The invention is particularly used in HIPERLAN. Other applications are not excluded. In particular, the length of the m-sequences and their repetition can be set according to the respective needs or requirements. M-sequences are particularly preferred because of their suitability for a combined estimation of channel impulse response and frequency offset are also other sequences with good autocorrelation properties can be used However, it is essential for the invention that not a single long synchronization sequence, but several short ones are used. Different sequences can be used that are optimal for different functions

In summary, it can be stated that the bit pattern according to the invention makes it possible to optimally implement antenna diversity at high data rates and in the presence of intersymbol interference

Claims

claims

1 preamble in a digital signal transmission system, characterized by several different bit sequences (m1 - m5), which are suitable for both packet synchronization and channel estimation

2 preamble according to claim 1, characterized in that the bit sequences (m1 - m5) maximum length sequences of a length of in particular about 31

3 preamble according to claim 1 or 2, characterized in that the bit sequences (m1 - m5) are repeated several times, in particular three times

4 receiver for a digital signal transmission system with a preamble according to one of claims 1 to 3, comprising

a) several antennas (1, 2, 3) and a switch (4) for sequential selection of the antennas (1, 2, 3),

b) a channel shock response estimator (6) for determining a channel shock response by evaluating at least one bit sequence (S1 - S3),

c) an evaluator (7) for determining the best channel impulse response in order to be able to subsequently detect a data part via the antenna (1 or 2 or 3) with the best reception

5 Receiver according to claim 4, characterized in that the evaluator (7) is designed to determine the shortest channel shock response

Receiver according to claim 4 or 5, characterized by a circuit (8) for determining the frequency offset

Transmitter for a digital signal transmission system with a preamble according to one of claims 1 to 3, characterized by a read-only memory with a stored bit pattern with several different bit sequences (m1 - m5), which are suitable for both packet synchronization and channel estimation

Transmitter for a digital signal transmission system with a preamble according to one of claims 1 to 3, characterized by a circuit for generating a bit pattern with several different bit sequences (m1 - m5), which are suitable for both packet synchronization and channel estimation

Transmitter according to claim 7 or 8, characterized in that the bit sequences (m1 - m5) are m-sequences, in particular the length 31, and are each repeated several times

A method for a digital signal transmission system having a preamble according to any one of claims 1 to 3, in which

a) within the preamble, one switches sequentially between several existing antennas (1, 2, 3), a complete sequence (S1 - S3) being tapped for each antenna (1, 2, 3),

b) on the basis of each sequence (S1 - S3) determines a channel impulse response

c) for a subsequent detection of the data that antenna (1 or 2 or 3) with the best channel impulse response is selected

11. The method according to claim 10, characterized in that the antenna (1 or 2 or 3) with the shortest channel impulse response is selected.

12. The method according to claim 10 or 11, characterized in that a frequency offset is determined on the basis of 2 time-spaced estimates of the channel impulse response.