DE3717315A1 - Method for synchronising a frame for subsequent decoding of additional information contained in digital signals - Google Patents

Abstract

Method for synchronising a frame for subsequent decoding of additional information contained in digital signals. Additional information is transmitted along with audio signals which are digitally coded in blocks in each case comprising 64 samples, each sample comprising 14 bits and one parity bit, in that individual parity bits (sync word) or a group of parity bits (scale factor, additional data) are negated or are not negated. The frame is synchronised through detection of the 4 parity bits with the information of the sync word. The search for the sync word is carried out bit-by-bit in that each bit of the data string is first subjected to the decoding algorithm, i.e. parity formation over 7 bits (1, 2, 3) and comparison of the parity bit thus created with the 15th bit of a 15-bit group (4), and that the 4th bit of the sync word is then searched for at 15-bit intervals in this decoded data string (5, 6, 7, 8). The method can be used for the transmission of digital audio signals in a future integrated-services broadband network (ISDN-B). <IMAGE>

Description

The invention relates to a method for synchronizing a Frame for the subsequent decoding of additional information to digital signals.

When transmitting digitally coded audio signals via standardized Transmission channels of the ISDN network will also be one additional digital information, such as a scale factor or Additional bits also transmitted, the channel capacity for the sound transmission is not increased.

In German patent application P 36 34 087.1 there is a "Process for the transmission of additional information to digital encoded audio signals ".

In this procedure, 64 14-bit audio signal words are used one additional parity bit each to protect the Audio signal words against bit errors during transmission Pulse frame of 2 ms length formed. To transfer a Additional information, such as a scale factor and additional bits and a sync word is made from the parity bits separate frame, the bits of which are spaced by 15 bit to each other in the data stream of the transmission channel. By inverting or not inverting the first four The sync word is transmitted with parity bits. The single ones Bits of the scale factor and the additional bits are indicated by Summary of five consecutive parity bits and also an inversion or a non-inversion transfer.  

Previous considerations assumed that the over carrying digitally coded audio signals with a useful bit rate of 1920 kbit / s for 4 monophonic or 2 stereophonic Sound channels in the frame recommended by the CCITT with 2048 kbit / s are transmitted and that the code words have a fixed reference to Have sync word of the pulse frame of the transmission system. A synchronization of the frames of the additional information is limited to the search for the sync word Additional information, the individual bits, as well as code words, a fixed time reference to the synchronous word of the pulse frame exhibit. The choice of the bit combination for this synchronous word the additional information is relatively uncritical.

A disadvantage of this prior art is that the over carrying data words, such as the audio signal words, and thus the frame of the additional information, before the transfer to the Pulse frames of the transmission system are synchronized have to.

The object of the invention is to provide a method for fast and secure synchronization of the frame of the additional information of each sound channel and thereby the simultaneous To enable recognition of the code word boundaries without first referring to the To have to synchronize the pulse frame of the transmission system.

This task is accomplished by the distinctive part of the main solved.  

Advantageous developments of this invention are in the Subclaims marked.

The invention has the advantage that the information from the digital coding of sound signals and additional information independent of word synchronization on the pulse frame of the transmission system.

It can therefore partial bit streams such. B. individual sound channels, transmitted transparently from the source to the sink and at the receiving location can go directly to this single channel be synchronized. This is of particular importance Advantage when transmitting two stereo sound channels in a data stream of 2048 kbit / s and with a spatial Separation of sources. At the place where both are combined Sound channels are then only the bit synchronism with each other and to establish the transmission system and a temporal The individual data bits are interleaved with one another to make.

It is also advantageous that the predetermined bit pattern the synchronous word of the additional information a quick first synchronization is possible and it against the pretense of a synchronous word is insensitive. In addition there is one given low sensitivity to bit errors since after only the synchronization word relevant parity bits are only evaluated after  repeated failure to recognize the synchronous word a new one Synchronization process is started.

A possible exemplary embodiment for carrying out the method according to the invention is explained in more detail in FIGS. 1 to 3.

Fig. 1 shows the coding of the parity bits of a frame.

Fig. 2 shows the circuit diagram of a synchronizing circuit and

Fig. 3 shows the optimization of the synchronous word.

In Fig. 1a a code word W is represented with a 14 bits per sample value transmitted and protected by a parity bit P from transmission errors sound signal.

The parity bit P protects the seven most significant bits of each coded sample of the analog audio signal from bit errors which can be caused by the transmission of this signal.

In Fig. 1b only the parity bits P 1 to P 64 of the 64 code words of a frame of these sound signals and thus also a frame of the associated additional information are shown and in Fig. 1c is the bit pattern of the sync word Sy , the 3-bit scale factor Sk 1 to Sk 3 and the nine additional bits Z 1 to Z 9 of the additional information are recorded.

Fig. 1d shows the linkage of a possible sequence of bits of the additional information, which by inverting or non-inverting individual parity bits for the synchronous word or as groups of five parity bits for coding the scale factor Sk 1 to Sk 3 and the additional bits Z 1 to Z 9 is reached. The frame of this additional information and thus also of the code words W of the audio signal assigned to this additional information is 2 ms.

To decode the code words W , only the word limits, that is to say the position of the parity bits P, have to be determined, while for the decoding of the additional information the frame start of this additional information must also be recognized by means of the synchronous word Sy .

The arrangement shown in FIG. 2 for synchronizing and decoding the additional information consists of a first serial / parallel converter 1 with an output register 2 , a parity generator 3 , an EXOR logic 4 , a second serial / parallel converter 5 , two inverters 6 and 7 , a NAND logic 8 , a synchronization logic 9 , a clock generator 10 and a decoder 11 .

The additional information is stamped on the parity bits of the code words as described in FIG. 1, so that this information must first be separated. For this purpose, the incoming serial data stream in the first serial / parallel converter 1 is converted into parallel 15-bit words and temporarily stored in the output register 2 . The parity generator 3 generates a parity bit from the first seven bits of these words, which is compared in the EXOR logic 4 with the 15th bit. The output bits of the EXOR logic 4 are read into a second serial / parallel converter 5 . As parallel 4-bit words, 4 bits with a spacing of 15 bits from each other are an evaluation logic which, depending on the bit pattern of the synchronous word (here: 1010), is composed of two inverters 6 and 7 and a NAND logic 8 , supplied to recognize this bit pattern.

During the search process for the synchronous word, both the first parallel / serial converter 1 , the output register 2 and thus the parity generator 3 as well as the second serial / parallel converter 5 and the synchronization logic 9 operated as a "flywheel circuit" with the bit clock of Bits of the code words controlled. After the evaluation logic has recognized the synchronous word for the first time, the output register 2 of the first serial / parallel converter 1 is driven with the word clock of the code words and the synchronization logic 9 with the frame clock of the additional information. Word clock and frame clock are generated in the clock generator 10 .

Only after the perfect synchronization is the decoder 11 released for obtaining the scale factor (Sk 1 to Sk 3 in FIG. 1) and the additional bits (Z 1 to Z 9 in FIG. 1). The respective bits of additional information are obtained here by majority vote.

Fig. 3 is a table showing possible combinations of bits of the synchronous word. There can only be such a bit combination in question, which experiences no interference from possible data bit combinations with undisturbed transmission channel. When looking at a data signal disturbed by bit errors, only the outlined combinations 0101 or 1010 are left of these possibilities as the pattern with the lowest pretense of pretense for the synchronous word. These two combinations can only be simulated if there are three bit errors in the combination, two bit errors in the bit sequence for an additional data bit or a bit error in the bit sequence for an additional data bit in the vicinity of the synchronous word, in each case at specific positions in the bit combinations.

The number of bit errors within the synchronization word is designated with n that the bit errors within an additional bit combination with k and those of the bit errors in an additional bit combination adjacent to the synchronization word with m which cause such a pretense.

Claims (4)

1. A method for synchronizing a frame for subsequent decoding of additional information for digital signals, in which the additional information per frame consists of a 4-bit synchronous word (Sy) , twelve additional bits (Sk, Z) and in which the synchronous word (Sy) by individually inverting or not inverting four consecutive parity bits (P) and each additional bit by inverting or not inverting a group of five consecutive parity bits (P) of a data stream consisting of digital signals of 14-bit code words (W) with each an associated parity bit (P) is constructed and that the coding is carried out so that inversion of the parity bit (P) represents a "1" and non-inversion a "0" of the additional information, characterized in that four bits of the data stream, each one Have a data word (W) spaced from one another and which are decoded in accordance with the coding regulations of the additional information, with the B it pattern of the synchronous word (Sy) are compared and that this "window" is shifted within the data stream by one bit until the synchronous word (Sy) is recognized by correspondence and that after recognition only every 15th bit of the data stream, that is each parity bit (P) - is queried for decoding the additional information. 2. The method according to claim 1, characterized in that after the synchronization only the parity bits (P) , which the sync word (Sy) is encoded, are queried in the frame spacing of the additional information for further checking the synchronicity. 3. The method according to claim 2, characterized in that the synchronization is restarted only after repeated failure to recognize the synchronous word (Sy) . 4. The method according to claim 3, characterized in that the bit pattern of the synchronous word (Sy) is a "1-0" sequence (1010 or 0101).