NO853535L - PROCEDURE FOR AA HIDDEN ERROR. - Google Patents

Description

The invention relates to a method for hiding errors

as stated in the introduction to patent claim 1.

From the journal Telcom Report 2 (1979), appendix "Digital-Ubertragungstechnik", pages 52-58, a PCM audio channel system for the transmission of stereo audio channels is known. The transmission of the sampling values takes place in companded form. The most significant bits in each code word corresponding to a sample value are protected with an additional parity bit. The protected highest-value bits are shuffled with the unprotected lower-value bits to avoid, as far as possible, that more than one protected bit is disturbed. If disturbance is detected, the last undisturbed code word is repeated, so a simple extrapolation is carried out. In the event of several disturbances, a soft disconnection of the signal occurs.

The task of the invention is to provide guidance on an improved method for hiding errors in connection with digital audio transmission.

Starting from the initially outlined stage

of the technique, the task is solved with the features that are specified as characteristic in patent claim 1.

In the specified method, the specified frame coating and mixing of bits is advantageous. Thanks to the bit shuffling within a code block, it is achieved that with the highest probability only a single bit in a code word is corrupted. With the specified code block structure, it is possible to protect up to nine most significant bits with a parity bit. By shuffling the code blocks, it is achieved that even in the case of bundles of disturbances of longer duration, two consecutive code words in a mono-tone channel are not disturbed. Thus, in the case of a disturbed code word, it is possible to obtain the corresponding sampling value by interpolation from the adjacent undisturbed code words. For the interpolation, two or more adjacent code words can be used. The hitherto known method for suppressing tricks, e.g. at the last sampling value before music breaks, can be retained.

The procedure will be explained in more detail under reference

to the drawing.

Fig. 1 shows possible error patterns when using the HDB-3 code. Fig. 2 shows an error pattern when using a scrambler. Fig. 3 shows the coverage of a multiplex frame with 512 bits. Fig. 4 is a principle connection core for realizing the method. Fig. 5 is a principle switching core for transmit-side bit shuffling. Fig. 6 is a principle connection diagram for the reception-side restoration of a continuous data stream, and

fig. 7 shows one form of multiplex frame.

According to fig. 4, two stereo audio channels A and B each with a data transfer rate of 1024 kbit/s are combined in a -transmit multiplexer T-MUX and transmitted at 2048 kbit per second. From the multiplex signal, both stereo sound channels A and B are obtained on the receiving side by means of a demultiplexer R-MUX. The sampling values are transmitted as code words containing 14 information bits and a parity bit. In addition, the multiplex signal contains, in a known manner, a frame marking word, a message marking word and channel-specific additional information.

On the transmission line, the so-called HDB3 code (CITT-G703) is often used. In this coding, a disturbed bit on the transmission path causes up to 3 bit errors during the duration of 4 bits (Fig. 1). Here, the disturbed bit must not be the first bit, as in fig. 1 is denoted by 0.

When transferring binary data, it is also common

to use a scrambler. The scrambler used for the transmission of tone channels causes, in the event of a disturbance of a single bit each time, 4 bit errors on the receiving side. In addition to the disturbed bit 0, a forgery also disturbs another 3 bits at distances of 15, 28 and 29 bits in the disturbance process (Fig. 2).

According to fig. 3, it is possible within a multiplex frame MUR of 512 bits to accommodate 8 and 8 code words of a left mono audio channel AL and of a right audio channel AR with a first stereo audio channel A and likewise to accommodate another stereo channel with the mono audio channels BL and BR. The code words are consecutively numbered 1 to 8. All the respective odd-numbered code words and likewise all even-numbered code words on a mono sound channel are combined into a code block CBL1 to CAR2. The designations for the first (left) and second (right) mono audio channels have been retained. The code blocks are sent out after a frame marking word RKW

in the order CBL1, CAL1, CBrl, CAR1 . Then follows additional information ZI-B comprising 8 bits, the message marking word MKW (also referred to as message word) and then the code blocks CBL2, CAL2, CBR2 and CAR2/ which only comprise even-numbered code words. At the end of a multiplex frame, the additional information ZI-A is transmitted for the stereo sound channel A/ an information which likewise comprises 8 bits. Each code block comprises 60 bits. These 60 bits are divided into 10 time sections ZA1-ZA10, each of which comprises 6 bits. In each of these time sections, each of the most significant 9 bits of each of the four code words is transmitted by a code block. First, all most significant bits are transmitted with bit no.

1 of the four code words of a block in the first time section ZA1. In the case of a block of code, e.g. the code block CBR1, which only contains odd-numbered code words on a mono audio channel, is transmitted first

...most significant bit of codeword CBR1 , then the most significant bit of fifth codeword BR5, while bit positions 4 and 5 are covered with the most significant bits of third codeword BR3 and seventh

■kodeod BR7. In fig. 3 (below), the lower digits indicate the respective code word number CR-Nr and the upper digits the bit numbers for the respective code word. Another time section is similarly occupied with the second most significant bits of the code words BR1, BR5, BR3 and BR7. The first nine time sections are similarly covered with the nine most significant bits. In the tenth time section ZA10, bit positions 1-6 are covered by the associated parity bits in a corresponding manner. The free bit positions are in turn filled up with the lower-value bits of the code words. Thus, first the bit positions 3 and 6 in the first time section ZA1 are occupied using the 10th and 11th bits of the first code word, then the bit positions 3 and 6 of the second time section ZA2 with the 12th and 13th.

bit, etc. Then the mapping takes place with the lower-value bits of another code word. In the case of a code block that only contains even-numbered code words, the allocation takes place in a similar way, i.e

the codewords 2, 6, 4, 8 take the place of the codewords 1, 5, 3 and 7. With this selected bit shuffling, even a disturbed bit of a codeword will not, due to the error propagation properties of the HDB3 code, falsify any further bits of the same codeword. The same applies when using a scrambler. In the case of short bundled disturbances, the bit errors are distributed among the different code words, so that in general only one bit of a code word is also falsified and the parity check can thus be used successfully.

In the case of the multiplex frame shown in fig. 3, if all possible bit combinations are permitted for the additional information ZI-A and ZI-B/ it is possible for a frame marking word and a message marking word to be mirrored. The last bits of additional information and the first bits of the frame marker word or of the message marker word then form a mirrored frame marker word or message marker word.

A simple remedy consists in transferring the additional information between two code blocks.

A favorable form of multiplex frame is shown in fig. 7. The code blocks are formed in the same way. However, they are then divided into two and two sub-code blocks. For example the original code block CA1I is divided into two sub-code blocks CAL11 and CAL12. F.first part code block in this case includes the first 30

bits and another partial code block the last 30 bits of the original code block. In the same way, all other original code blocks are split. The partial code blocks are shuffled together. In the specified multiplex frame, there are three further sub-code blocks between two contiguous sub-code blocks, for example CAL1 1 and CAL12X. The additional information ZI is divided into blocks of 4 bits and is transmitted respectively after the fifth and seventh sub-code blocks after the frame marking word and likewise after the fifth and seventh sub-code blocks after the message marking word MKW. These blocks of 4 bits of additional information each contain two consecutive bits of the additional information for a channel, suitably first two and two bits of additional information for the right mono sound channel and then two bits for the left mono sound channel. With the selected formation of the multiplex frame, the additional information is applied

the respective last two bits of an original audio channel and the first two bits of the next original audio channel. In the case of incomplete coverage of the audio channels, an original transmission channel is no longer used for the additional information either.

Several of the multiplex frames shown in fig. 3 or

7, can again be summarized into a multiplex system of a higher order.

Figs. 5 and 6 serve to further elucidate the principle-connection system in fig. 4. The code words of a stereo sound channel are supplied to a data protection unit 11 in a transmitter-side processing part 1 of which there are two. In the data protection unit, the parity bit is formed and added in connection with each code word. The parity-protected code words are then introduced into a transmission-side write-read storage T-RAM and read out bit by bit from this in the one in fig. 3 showed sequence at double speed. Here, the address management takes place via a transmitter-side read storage T-PROM. The takt supply and the necessary control, e.g. at a counter for the read storage T-PROM/ is not shown. The send-side processing part occurs twice. By means of the multiplexer 12, the data blocks read out at double speed in the first stereo sound channel A are joined together with those in the second stereo sound channel

B.

In fig. 6 shows the twice-occurring reception-side processing part 2. By means of a demultiplexer 23, the data blocks on the first and second stereo sound channels are separately fed into two reception-side processing parts 2. The data blocks are written into a reception-side write-read storage R-RAM, from which the code blocks , controlled by a receiving-side read-store R-PROM, are read out in original order (Fig. 3, upper arrangement of the code words). An error detector 21 constantly checks the code words, while in an interpolation link 22 e.g. a mean value formation occurs. Shows e.g. the codeword BR3 is disturbed, the mean value of the codewords BR2 and BR4 is read out instead of the disturbed codeword BR3. In order to achieve a chronologically correct release, both are needed

in the interpolation link and in the error detector running time term, e.g. shift registers.

When it comes to realizing the connection, there are many possible variants, the execution of which, however, does not present difficulties for professionals.

Claims (10)

1. Method for detecting errors in digital audio transmission on two stereo audio channels (A, B) each containing mono audio channels (AL, AR; BL, BR), within a multiplex frame whose frame marker word, message marker word and length correspond to CCITT-G732, where the most significant bits of each codeword representing a sampling value are secured with a parity bit (P) and the disturbed codewords on the receiving side are obtained from the adjacent codewords by interpolation and/or extrapolation, characterized by that within a multiplex frame (MUR) for each mono audio channel (AL, AR; BL, BR) 8 code words (AL1 to AL8; AR1 to BL1...), each with 14 bits and a parity bit (P), are transmitted, that four and four odd-numbered code words (AL1, AL3, AL5, . AL7; AR1...) and four and four even-numbered code words (AL2, AL4, AL8; AR2...) in each mono audio channel (AL, AR, BL, BR) of the multiplex frame (MUR) are combined into one code block (CAL1, CAR1 , CBL1, CBR1; CAL2...), that the code blocks of the two stereo sound channels (A, B) are mixed together, that within each code block (CBL1, CAL1,...) periodically during time periods (ZA1 to ZA10) which each comprise 6 bits of each of the four associated code words (BR1, BR3, BR5, BR7), are placed one by one of the nine most significant bits of the same order as well as the associated parity bits (1P, 3P, 5P, 7P), and that the remaining bit positions are occupied with the lower-value bits. 2. Method as stated in claim 1, characterized in that the bit positions 1, 2, 4 and 5 within each time section (ZA1-ZA10) are occupied with the highest-value bits. 3. Method as stated in claim 2, characterized in that the bit positions 1, 2, 4 and 5 of the time sections (ZA1-ZA10) are occupied with one and the same of the nine most significant bits and the parity bit for the first, third, second and fourth code words ( BR1, BR5, BR3, BR7) in a code block (CBR1). 4. Method as stated in claim 3, characterized in that the unoccupied bit positions 3 and 6 in the time sections (ZA1-ZA10) are occupied in turn with bits 10-14 of the first, third, second and fourth code words (BR1, BR5, BR3, BR7) at the code block (CBR1). 5. Method as specified in one of claims 1-4, characterized in that seven to nine most significant bits of each code word (AL1, AL2,...) are secured with a parity bit. 6. Method as stated in claim 1, characterized in that between the transmission of two code blocks (CBR1, CBR2) of a mono sound channel (BR) three further code blocks (CAR1, CBL2, CAL2) of the other three mono sound are transmitted channels (AR, BL, AL). 7. Procedure as stated in claim 1, characterized by that a frame marking word of 8 bits length is transmitted at the beginning of each multiplex frame (MUR), that eight bits of additional information (ZI-B) for the first stereo audio channel (B) are transmitted in the first half of the multiplex frame (MUR), that at the beginning of the second half of the multiplex frame (MUR) a message marking word (MKW) comprising eight bits is transmitted, and that in the second half of the multiplex frame (UR) eight bits of additional information (ZI-A) are transmitted again for another stereo sound channel (A ). 8. Method as stated in claim 7, characterized in that the additional information (ZI-A, ZI-B) for each stereo sound channel (A, B) is each time transmitted between two code blocks (CBL1 and CAL1,, CAL1 and CBR1,...) . 9. Method as stated in one of the claims 1-5, characterized by that each code block (CBL1, CAL1,...) is divided into two equally sized code sub-blocks (CBL11, CBL12; CAL11, CAL12,...), that the additional information (ZI) is each time divided into blocks of 4 bits, of which two and two successive bits are assigned to a mono sound channel (AR, AL), and that the blocks with 4 bits of additional information (ZI) each time after the fifth and seventh code part blocks (CBR12, CA12,...) are transmitted after the frame marking word (RKW) and the message marking word (MKW). 10. Method as stated in claim 1, characterized in that 2-n (n = 2,3,4...) stereo sound channels are combined into a multiplex signal.