DE4027496A1 - Data spreading for coded digital information transmission system - using similar matrix at transmission and reception ends with line write-in and column read=out - Google Patents

Abstract

The coded data to be transmitted is entered in respective lines of a matrix, with column read-out of the latter for supplying to the transmission channel. At the reception end the data is entered in the columns of a similar matrix which is read out in lines, for supplying to a decoder. The reliability of the transmission channel is evaluated at discrete time points at the reception end, the obtained channel information represented in the matrix by a word with a given number of bits. USE/ADVANTAGE - E.g. for mobile radio or satellite communication. High decoding speed.

Description

The invention relates to a spreading method for transmission encoded digital messages, in which encoded data line by line in a matrix and before the transfer column can be read out via a channel, and at which the coded and spread Da First, columns in a matrix of the same dimension read in, then read out from this line by line and on be fed to a decoder.

When transmitting digital messages, they become too supporting information units, d. H. the bits, by interference conditions on the transmission line and due to the intrinsic noise of the Receiving device falsified at this receiving device. The rate at which such erroneous bits occur is referred to as error bit rate (BER); it depends on the Type of interference in the transmission and the used Transmission process and is a function of the signal Noise ratio.

In performance-limited communication systems, such as for example in satellite communication, are used for ver improvement of the bit error rate advantageously channel coding method applied to thereby at a given Sig nal-noise ratio to improve the bit error rate.  

With coded transmission via fading channels, as with for example in mobile communications, it is advantageous to add channels status information in the decoding at the receiving end to acquire. So far, however, spreading methods have been used, at which bundle errors are resolved into individual errors, however, no information is conveyed to the decoder, that errors have occurred bundled. This can be with strong Fading to a loss of 4 dB to 5 dB of required signal S / N ratio for a given bit error rate.

The object of the invention is therefore to improve the Qua lity of a digital transmission or the bit error rate Decoder channel status information (KZI) in the corresponding Way to dispense. According to the invention, this is done with a Spreading method for the transmission of coded, digital Nach judge by the preamble of claim 1 by the note male reached in its characteristic part. Beneficial Further training is the subject of the subclaims.

This is the case with the spreading method according to the invention achieved that the channel output at discrete times because a measure of the reliability of the transmission that So-called channel status information (KZI), taken and in same way as the corresponding received data is despread, and then the decoder for decoding Is made available. According to an advantageous further Education of the invention, the derivation of the Kanalzu takes place status information in a separate facility. Thereby parts of the demodulator can be used, and the Complexity of the receiving device including decoder is reduced.

Furthermore, in an advantageous development of the inventions according to the spreading method the channel status information be quantized in a way that fits the channel and which is the channel status information in the form of m- Represents bit wide words. By using a  channel state information quantized in this way is in particular the implementation with an increasingly flexible Digital technology favors. Advantageously, the Ent Spreading of the channel status information parallel to the despread data is carried out, which increases the ver working speed is achievable. Another before partial simplification in the spreading according to the invention driving is that the channel status information on (1) bit per column of the despreading matrix can be reduced, resulting in an even higher processing speed is enough.

It is particularly advantageous for the spreading method according to the invention that the decoder is not supplied with the actual channel status information, but with calculated metrics which include the respective channel status information and are stored in metric tables with 2 ^m elements, so that when they are accessed Metrics the channel status information represents an m-bit address, which points to the corresponding metric, which is fed directly to the decoder. This measure frees the decoder from the calculation of the metrics, and a higher decoding speed is achieved.

The channel status information can also be advantageous can be taken from a channel estimator which measures a level solution of a pilot tone transmission or a consideration of Carry out latching signals of the clock or carrier control loop can.

The invention based on preferred from management forms with reference to the attached drawing explained in detail. Show it:

Figure 1 shows schematically in the form of a block diagram an advantageous embodiment for performing the inventive spreading method.

Fig. 2 shows schematically a spatial spreader and despread zermatrix with synchronization words, and channel state information memory, and

Fig. 3 is a FIG. 2 corresponding view of a spreader and Entspreizermatrix with only 1 bit Ka nalzustandsinformation per column.

In Fig. 1, a preferred embodiment for performing the spreading method according to the invention is shown in the form of a block diagram. Here, coded bits from a coder 1 are buffered in an i _* k matrix 2 , where i denotes the row length and k the column length of the matrix. The intermediate storage takes place in such a way that the bits arriving from the coder 1 are entered line by line into the matrix 2 and then read out in columns. This is called spreading.

Before the coded and now spread bits are passed on to a downstream digital modulator 3 , synchronization information is also used in the spreader 2 . At the beginning of the matrix content (i _* bits), this information consists of an SL bit-long frame synchronization word R, which is an inverse column synchronization word, and SL bit long column synchronization words S, which correspond to the length after every k bits to be inserted in a column. This corresponds in the schematic representation of a spreader and despreading matrix in FIG. 2 to its foremost level. A sequence supplemented in the manner described above is fed to the digital modulator 3 and transmitted from there via a fading channel 4 .

On the reception side, channel status information is taken, for example, from an automatic level control unit (AGC) 5 , from a channel estimator 12 or from a demodulator 6 and fed to a quantizer 11 . (Although channel status information is generally supplied by only one of the units 5 , 12 and 6 given above, all three units are shown schematically in FIG. 1, since the channel status information can also be taken from a simultaneous consideration or consideration under certain conditions several sizes can result). In the demodulator 6 , the coded, now spread and supplemented by the synchronization information bits are regenerated.

In the despreading provided according to the invention, a synchronization is thus first carried out in a synchronization unit 7 , which in turn consists of an initial synchronization and a resynchronization. An initial synchronization is carried out by recognizing three (3) consecutive correct column synchronization words S and a correctly recognized frame synchronization word R.

Here, a resynchronization is initiated if more than the specified number ( 0 ............. 99 ), for example 25 consecutive incorrect column synchronization words occur within a specified window, which is, for example, 8 bits wide and around -1.0 or +1 bit is shifted. A shift of +1 bit per column is recognized and is compared with the beginning of the next column. The synchronization and despreading are carried out in a working matrix of dimension i _* (k + 8) _* (m + 1).

After synchronization, the working matrix is filled with one (1) frame synchronization word, (i-1) column synchronization words, i _* k received coded data bits and with k _* i channel state information words of a width m. The above-mentioned content of the matrix is schematized in Fig. 2.

At the receiving end, data despreading takes place in a data despreader 8 by reading out the data bits line by line, while a despreading of the channel state information in a channel state despreader 9 is achieved by line by line reading out the m-bit wide channel state information. This reading can be carried out simultaneously and in parallel. The coded data bits and the associated m-bit channel status information are now available on a downstream decoder 10 . The word width of the channel status information is adapted to the code used in each case, with "Erasure Decoding" being m = 1 for block codes in FIG. 2, while m = 3 is for example for convolutional codes.

When the m-bit channel status information is read out, a comparison table, a so-called tabla look-up, can be linked in a metric table; This allows the de coder 10 pre-calculated metrics, instead of the Kanalzu state information are provided. In this case, the comparison table or the table look-up is added to the despreading.

According to a further advantageous embodiment of the invention, only one (1) bit per column of the spreading matrix is transferred to the decoder 10 , which indicates whether a bundling error has occurred in the column. The form of such a work matrix is shown schematically in FIG. 3 in a representation analogous to FIG. 2.

Claims (11)

1.Spreading method for the transmission of coded, digital messages, in which coded data are transmitted line by line in a matrix and read out column by column before transmission via a channel, and in which the coded and spread data is first read in columns in a matrix of the same dimension , then read from this line by line and fed to a decoder, characterized in that points on the receiving end at the channel output at discrete times as a measure of the reliability of a transmission, each time a channel status information is extracted, in the same way as the corresponding received data, and then spreads accordingly Decoder ( 10 ) for decoding is supplied. 2. Spreading method according to claim 1, characterized in that the channel status information is derived in a separate device ( 5 ; 6 ; 12 ). 3. Spreading method according to claim 1, characterized in that for obtaining the channel state information, this is quantized in a channel-adapted manner in a quantizer ( 11 ) and is presented in the form of m-bit wide words. 4. spreading method according to claim 1, characterized records that the channel status information is in parallel to despread the data. 5. spreading method according to claim 1, characterized in that to simplify the method, only 1-bit channel status information per column of a de-spreading matrix is applied to the decoder ( 10 ). 6. spreading method according to claim 1, characterized records that a reception-side despreading with Using the channel status information is synchronized. 7. Spreading method according to claims 1 and 3, characterized in that instead of the channel status information, fully calculated metrics are used, in which the respective channel status information is included, and which are stored in metric tables with 2 ^m elements, and that when accessing these metrics represent the channel state information an m-bit address, which indicates the corresponding metric which is fed directly to the decoder ( 10 ). 8. spreading method according to claims 1 and 2, characterized in that the channel status information is derived from the level signal of an automatic level control (AGC) unit ( 5 ). 9. Spreading method according to claims 1 and 2, characterized in that the channel state information is taken from a channel estimator ( 12 ). 10. spreading method according to claim 9, characterized records that the channel estimate in the noiseless Level measurement is carried out with a pilot tone transmission. 11. Spreading method according to claim 9, characterized records that in the channel estimation lock signals the clock or carrier control loop can be used.