DE19921504A1 - Method and circuit arrangement for determining quality information about the transmission quality of a speech signal in a digital transmission system - Google Patents

Abstract

In digital transmission systems, such as in mobile radio systems, the speech quality essentially depends on the correctibility of the channel decoding method. To improve the voice quality, error masking measures are taken, the effectiveness of which is determined by the accuracy of the quality information of the channel transmission quality. According to the invention, known quality information is combined and transformed such that it is suitable as reliable input parameters for the error masking measures. By taking the bad frame indicator BFI into account when selecting the transformation regulations, different transformation regulations can be adapted to the respective transmission conditions. The method can be easily implemented if a transformation unit (4) is inserted between the channel decoder (1) and the error concealment unit (2) in an upstream channel.

Description

In digital transmission systems, such as in mobile radio systems according to the GSM standard, the quality of the transmitted depends Speech signals significantly from the correction ability of the Channel decoding process. Nevertheless, it is inevitable that the channel decoding residual bit errors occur which is a noticeable result in deteriorated speech quality. To this lack Speech quality improvement is usually done before or after Speech decoding. Which type These error concealment measures depend largely on the Accuracy of a quality information, which is a measure of Transmission quality of the channel and ultimately for the voice quality.

So is a so-called soft-output Viterbi algorithm, SOVA for short, known with which a quality value is supplied for each decoded bit, see. Hagenauer J., Hoeher P .: A Viterbi Algorithm with Soft-Decision Outputs and its Applications, Proc. of GLOBECOM '89, pages 1680-1686, Dallas, Texas, November 1989. Although this algorithm is relatively simple realizable, but it provides quality information that the voice quality not yet improve satisfactorily.

It is also an error concealment technique in a TDMA radio system known with the quality information from the channel decoding process  be won, cf. US 5,502,713. In a so-called soft value Calculator become weighting factors from quality information calculated with which currently and previously received parameters of the Speech coding method can be evaluated and interpolated.

With the invention, the object is achieved, a method and a Specify circuitry with which known Quality information is improved so that for Error masking measures more suitable input parameters for To be available.

This object is achieved with the method described in the first claim and with the circuit arrangement described in the seventh claim solved.

The essence of the invention is that quality information before of channel decoding combined with those after channel decoding be followed by a transformation unit different, adapted to the transmission conditions Transformation regulations are processed so that an improved Quality information for a subsequent error concealment unit is formed.

The invention will now be explained in more detail using an exemplary embodiment.

Show in the accompanying drawing

Fig. 1 is a block diagram of the circuit arrangement according to the invention and

Fig. 2 is a schematic representation of data blocks at the input of an error concealment unit.

Referring to FIG. 1, a circuit arrangement for speech transmission in the direction of a subscriber terminal (engl. Upstream) in a digital mobile radio system comprising a channel decoder 1, an error concealment unit 2, and a speech decoder 3, and according to the invention from a transformation unit 4. The channel decoder 1, an input signal y 'supplied from the channel decoder 1 the reasons of error protection in the transmitter error protection code generated decoded and x as an output signal' provides. Some of the transmitted data can also be transmitted without an error protection code and is shown in FIG. 1 as a data signal z '. The error protection code can either be generated continuously or in each case for a data block of length bl. In block-based processing is 2, the number of the input 2 of the channel decoder 1 is shown in FIG. Bl of the error concealment unit of a number of M input bits of the data signal z 'without error protection code and a number L input bits of the output signal x' together. From the channel decoder 1, a bit error rate BER (x ') of the output signal x' of the channel decoder 1 is estimated. The bit error rate is also referred to as soft output or generally as quality information. A bit error rate BER (z ') of the data signal z' without an error protection code can be estimated, for example, by a receiver or an equalizer. The estimated quality information BER (x ') and BER (z') thus available are now supplied as input variables to the transformation unit 4 and are further processed in accordance with the following regulations in such a way that the error concealment unit 2 is supplied with improved quality information in order to determine the quality of the output signal s to increase the speech decoder 3 .

Transformation regulations a) Separate averaging from quality information

It is assumed that there are L values x _i 'and M values z _i ' per block. BERn (x ') and BERn (z') denote the values of the biff error rate BER (x ') and BER (z') improved by the transformation.

b) Common averaging from available quality information

The assumptions described under a) also apply here.

c) Averaging with selection criteria, variant 1

The improved estimated value BERn (x ') of the bit error rate BER (x') estimated by the channel decoder 1 is determined from the maximum of the individual picture error rates BER (x _i ') estimated by the channel decoder 1 and a bit error _probability BER _tmP . The bit error probability BER _tmp results from equation (1) from the mean value previously described under a).

d) Averaging with selection criteria, variant 2

BERn (x _i ') = max [BER (x _i ', BER, _tmp ]

The transformation _rule described here differs from that described under c) in that it determines the bit error _probability BER _tmP .

The ones mentioned in c) and d) in the transformation regulations Parameters a, b, c and d are dependent on the respective Transmission modes, such as GSM full rate or GSM enhanced full rate, chosen.

It is particularly advantageous to make the execution of the individual process steps dependent on a so-called bad frame indicator BFI. Depending on the quality of the transmission conditions, the signal BFI is set to "1" if the transmission conditions are poor and "0" if the transmission conditions are good. Referring to FIG. 1, the signal BFI, if necessary, the error concealment unit 2, the speech decoder 3 and the transformation unit 4 is supplied, so that so that the modules can be activated or deactivated. In addition to activating / deactivating the above-mentioned modules, the BFI signal can be linked to the transformation regulations. This ensures that the reliability of the quality information is better adapted to the transmission conditions. For example, with the transformation rule described under c), the estimated bit error rate BERn (x ') can be increased so that an underestimation of the bit error rate by the soft output Viterbi algorithm can be compensated for in the event of poor transmission conditions, i.e. with BFI = 1. With good transmission conditions, that is, with BFI = 0, the use of the transformation rule mentioned under d) is more suitable in order to reduce the bit error rate and thus to avoid effects of model errors in the transmission system.

With the method according to the invention, more reliable quality information is obtained compared to the known prior art, so that an improved parameter estimation for error concealment measures is possible. A better speech quality after the speech decoder 3 is thus achieved. The method can be implemented with less effort in comparison to known more complex algorithms, since only one tronformation unit 4 has to be inserted between channel decoder 1 and error concealment unit 2 .

The circuit arrangement shown in FIG. 1 can be implemented as an integrated circuit, the following integration options being selectable if necessary:

• - Channel decoder 1 and transformation unit 4
• - Error concealment unit 2 and speech decoder 3
• - Channel decoder 1 , transformation unit 4 and
• - fault concealment unit 2
• - Transformation unit 4 and error concealment unit 2 .

Claims (8)

1. A method for determining quality information about the transmission quality of a voice signal which reaches a subscriber in a digital transmission system via a channel decoder ( 1 ) and via an error concealment unit ( 2 ) and via a speech decoder ( 3 ) and in which the channel decoder ( 1 ) a first picture error rate (BER (x ')) is estimated from a first number (y') input bits and a second bit error rate (BER (z ')) is estimated from a second number (z') input bits from a receiver or equalizer , characterized in that by means of a transformation unit ( 4 ) the first bit error rate (BER (x ')) and the second bit error rate (BER (z')) are processed and combined in accordance with a transformation rule in such a way that quality information as an input parameter for the error concealment unit ( 2 ) is determined by which an improvement in the speech quality is brought about. 2. The method according to claim 1, characterized in that by means of the transformation unit ( 4 ) a first mean value (BERn (x ')) from the block-by-bit first bit error rates (BER (x')) and a second mean value (BERn (x ') ) is formed from the second bit error rates (BER (z ')) determined in blocks. 3. The method according to claim 1, characterized in that a common mean value is formed by means of the transiormation unit ( 4 ) from the first image error rates (BER (x ')) and the second bit error rates (BER (z'))
4. The method according to claim 1, characterized in that by means of the transformation unit ( 4 ) a quality measure is determined according to a first selection criterion from the first image error rates (BER (x '))
5. The method according to claim 1, characterized in that by means of the transformation unit ( 4 ) a quality measure is determined according to a second selection criterion from the first bit error rates (BER (x '))
6. The method according to claim 1, characterized in that the transformation rule of the transformation unit ( 4 ) is selected depending on the value of a so-called bad frame indicator (BFI). 7. Circuit arrangement for realizing the method, characterized in that between the channel decoder ( 1 ) and the error concealment unit ( 2 ), the transformation unit ( 4 ) is connected such that the output of the channel decoder ( 1 ) is connected to a first input of the transformation unit ( 4 ), that the second image error rate (BER (z ')) supplied by a receiver or equalizer is at a second input of the transformation unit ( 4 ) and that the outputs of the transformation unit ( 4 ) are connected to the error concealment unit ( 2 ) are connected. 8. Circuit arrangement according to claim 7, characterized in that a third input of the transformation unit ( 4 ) and the error concealment unit ( 2 ) are connected to a line providing the bad frame indicator (BFI).