DE19531374A1 - Audio and-or video signal transmission method - Google Patents

Abstract

Audio and/or video signals are transmitted via telecommunication networks from a transmission terminal to a receiver terminal. The signals to be transmitted are sampled, digitised and coded to form signal responses. The least significant bit is replaced with a signalling information bit before being transmitted. At the receiver end, the signalling information bit is removed and used to combine the useful data. The signalling information bit is replaced by the least significant bit to reform the original signal response.

Description

To the existing infrastructure of today's telecommunications networks and especially the ISDN under construction worldwide Online signal transmission of digitized audio signals with egg Using a bandwidth of <3.1 kHz are coding methods required, which differs from the coding method for conventional distinguish between telephone signals.

For digital transmission of high quality speech over audio lines are under other so-called audio encoder and decoder according CCITT standard G.722 used. The coding according to G.722 uses subband coding with ADPCM (SB-ADPCM, i.e. subband adaptive Differential Pulse Code Modulation) to a 64 kbit / s channel transmit the user information with a 7 kHz bandwidth. The encoded information is used for transmissions in ISDN systems with frame alignment and bit rate mapping information mations that comply with CCITT recommendation H.221 can. This CCITT recommendation H.221 is in the useful signal word integrated in such a way that the bit lowest who activity is separated on the transmission side and by the in the emp given signaling bit is replaced. In the playback of the audio or video word on the receiving side decodes the word corrupted by the signaling bit. As a result, the reception quality deteriorates (increased Noise).

The invention is based on the problem of a method and an arrangement of the type mentioned with a verbes to specify reception quality.  

According to the invention, this problem is solved with a method or solved with an arrangement which in the claims are defined.

The invention is characterized by the advantage that the im State of the art tolerated signal corruption of the coded Video or audio word or part of a sol Chen word is avoided. This takes place according to the invention through that a transmit side from the video or audio word removed bit information ("Bit LSB Io") at the location of the Audio or video word in an information buffer (TFIFO) is directed and corresponding to the transmission of the, with systematically added bits generated audio or video word tes, is transmitted to the receiving location: this bit information in the correct position in the falsified Audio or video word inserted so that the source words are full be constantly restored. The receiving side The audio or video word is the same as that on the transmission side dete. This results in an optimal reception quality. The The principle of lossless transmission is instrumented.

The invention will now be described with reference to the figures.

It shows

Fig. 1 shows a transmitter-side circuit arrangement for performing the method according to the invention;

Fig. 2 shows a coding device in a transmission-side circuit arrangement according to Fig. 1;

Fig. 3 is a gnalisierungsinformationsworte formed by the transmission side circuit arrangement of Figure 1 the frame structure for the useful signal Si. and

Fig. 4 shows a receiving circuit arrangement for carrying out the method according to the invention.

The transmission-side circuit arrangement for carrying out the method has a telecommunications terminal T1 or an audio and / or video terminal which, for example, is able to process a signal with a bandwidth that exceeds the usual telephone bandwidth. The terminal T1 shown in FIG. 1 is able to process twice the telephone bandwidth, in particular 7 kHz.

The audio and / or video signals to be transmitted are in the transmitting end terminal T1 in a manner known per se stet and by a processor TDSP, which also functions of an A / D converter has digitized. This makes Nutzsi signal words NW formed, which consist in particular of 8 bits, and are coded according to G.722. This signal NW becomes the after switched unit TR supplied.

The processor TDSP also has the function shown in FIG. 2: The data digitized by the A / D converter A / D is fed to a quadrature mirror filter QMF, which is implemented in particular by two linear, non-recursive filters is and forms the input part of a G.722 coding device. The filter QMF splits the signal bands at 50 to 4000 Hz and 4000 Hz to 7000 Hz and forwards these output variables with a frequency of 8 kHz to a lower-subband ADPCM coding device ENCL and to an upper-sub-band ADPCM coding device ENCH .

The coding of the lower and the upper subband is done in a manner known per se. A multiplexer MUX trains the output values IH, IL of the two coding devices ENCH, ENCL a 64 kbit / s output signal I in one octet shape.

In the device TR, at least the bit LSB Io (Least Significant Bit, FIG. 1) of the least significant value is decoupled from the digitized and encoded audio and / or video signals NW by a processor (not shown) and in a FIFO memory TFIFO ( Fig. 1) saved. The corresponding memory cells are numbered from 1 to 80.

A frame number information is also stored in this memory TFIFO tion, which is formed according to H.221, registered.

Furthermore, a signaling information bit Ih is written into the useful signal words NW, specifically at the location of the hidden bit LSB Io. In this way, useful signal / signaling information words NSW to be transmitted are formed, the signaling information bits Ih forming a predeterminable number of successive useful signal / signaling information words signaling words which, in addition to frame alignment information FAS and bit rate assignment information BAS, can contain further organizational information AC ( FIG. 1 and 3). The type of signaling information results from the position of this signaling information in blocks, which are formed from the useful signal / signaling information words.

According to recommendation H.221, the user data flow (sum of the user signal / signaling words NSW) is divided into frames of 80 octets each ( FIG. 3). 16 successive frames are combined to form a so-called multi-frame (multiframe). 80 bits of the same value form a subchannel in a frame. The sub-channel of the least significant bits is used as the bit rate mapping information service channel. The frame alignment signal (FAS) is arranged in bits 1 to 8 of the service channel, while the bit alignment signal BAS is arranged in bits 9 to 16 of the service channel. The last 64 bits are available for an application channel (Application Channel AC).

Each multi-frame is divided into 8 sub-multi-frames. It will between straight frames with the numbers 0, 2,. . . , 14 and un straight frame with the numbers 1, 3,. . . , 15 differentiated.

A terminal adapter T TA-X.21 prepares the useful signal / signaling information words NSW and the hidden bits LSB Io of the least value as well as the frame number information in such a way that the useful signal / signaling information words NSW containing the signaling information bits Ih included, are transmitted in at least one user data channel (ISDN user data channels B1, B2) via a transmission line, in particular a telecommunications network ISDN, from the transmitter-side arrangement T1, TR to the receiver-side arrangement RE, T2 ( FIG. 4), while the hidden bits LSB Io der least importance with the frame number information in a signaling channel D are transmitted. The frame number information is preferably transmitted in words and this in blocks. The bits LSB Io are contained in a block in the first 10 words and the frame number information is contained in the 11th word.

As shown in FIG. 4, the useful signal / signaling information words NSW with the bits Ih (FAS, BAS, AC) transmitted over the telecommunications network ISDN and the hidden bits LSB Io transmitted separately therefrom are initially a terminal adapter R TA-X .21 supplied, which separates the B-channel and the D-channel information. The downstream synchronizer B-SYN aligns the B-channel data stream based on the administration information (FAS, BAS, AC) in block-synchronous fashion with the transmission side.

A downstream of the B-SYN synchronizer, in the figure Processor, not shown, separates the bits Ih or hides them.  

The bits LSB Io separated by the terminal adapter R TA-X.21 the least significant are stored in a FIFO memory R FIFO registered.

The synchronization for the bits transmitted in the D channel based on the frame number transmitted in the D channel information, wrapped in characteristic guide bits, carried out by a synchronizer D-SYN. With that the Reconstructed block structure for the Ih bits.

The one following the B-SYN synchronizer, in the figure Processor, not shown, now couples the Bits LSB Io in the correct position in the words NSW to the original position of the bits Ih.

The useful signal words NW are thus restored.

After aligning the blocks or words are in vice versa reverse order (with regard to the procedures) each bit Ih through that in the D channel transferred associated bit LSB Io replaced.

The synchronizers B-SYN; D-SYN do not work in one the reconstruction of the data stream aligned according to blocks transmission-side block structure. In this block structure results the type of information from their position in the block. There is a 3-bit information in the 10-byte Administra tion information word, described in the H.242 recommendation the frame number. This frame number is also in the structure ture of the bits filtered or separated at the sending location low value LSB Io added and by a "Structure" separated from these bits, i. H. in the additional channel (D channel) at least 11 bytes are transmitted, with 10 bytes that contain LSB Io information.  

The useful signal words NW formed on the reception side correspond the useful signal words NW prepared on the transmission side.

The useful signal words formed in the unit RE are now audio decoding in accordance with G.722 in the processor RDSP gen and digital / analog converted (D / A converter D / A).

Finally, the analog signal can be adequately reproduced device with the appropriate bandwidth. Is only a telephone terminal with reduced bandwidth available, so playback takes place only with this reduced bandwidth and thus with limited playback quality.

If, for example, the Qutband signaling channel (here: D channel) is not available (e.g. temporary failure), the decoding of the user channel falsified with H.221 information is provided as the default value such that if frame number information is missing (the otherwise would be transmitted in the D channel), a signal is formed on the receiving side, which has a quantization noise 6 dB higher than the coded te digital signal. In the receiving-side device RE, only the steps shown in FIG. 4 are carried out, which are specified in the branch RTA-X.21-SYN-H.221 "couple LSB".

The synchronizers B-SYN, D-SYN can be used as separate units ten ("ballast box") that are behind the emp upstream terminal adapter R TA-X.21 or in front of the on direction T2 can be switched.

In the context of the invention, the synchronization between Sender (T1, TR) and receiver (RE, T2) via an inbound signal frame alignment signal (FAS), bit rate alloca tion signal (BAS) and application code (AC) in particular ge according to CCITT recommendation Rec. H.221. This inband signaling is the data stream of the source coded  Audio information, imprinted in accordance with CCITT recommendation G.722, where the last bit of each octet (user data word) replaces becomes.

During synchronization via in-band signaling is carried out, the transmission is based on the invention the useful signal / signaling information words NSW too still on complementary out-of-band signaling, whereby in particular the ISDN channels B (useful channel) and D (Signaling channel) can be used.

This structure is suitable for being assigned to the useful channel B in Signaling channel D to transmit information. As part of The invention uses useful information, namely the bits LSB Io, transmitted in signaling channel D, which is otherwise off finally the transmission of call control information is used; Signaling information Ih will on the other hand, transmitted in the useful channel B. With the invention Use of the D channel makes this a comprehensive use fed. In the prior art, its existing capaci not fully used in normal applications.

It can be provided according to the invention that several Nutzda tenkanäle B for the transmission of the useful signal / Signalisie NSW information words can be used. It can be for each the user data channel B has its own signaling channel D. be seen.

Claims (2)

1. Method for the transmission of audio and / or video signals via a telecommunications network from a transmitting end device (T1) to a receiving end device (T2), the telecommunication network transmission lines having at least one useful data channel (B1, B2) and a signaling channel ( D) has
consisting of the following process steps, which are carried out on the side,
Audio and / or video signals to be transmitted are sampled, digitized, encoded and processed into useful signal words (NW), in particular consisting of 8 bits,
from the useful signal words (NW) at least the bit (LSB Io) of the lowest value is hidden, in place of the useful signal bit (LSB Io) of the lowest value a signaling information bit (Ih) is faded in and in this way useful signals to be transmitted are / Signaling information words (NSW) are formed, the signaling information bits (Ih) forming a predeterminable number of successive useful signal / signaling information words (NSW) signaling information words (SW) which, in addition to frame alignment information (FAS) and bit rate assignment information (BAS), contain further organizational information (AC) The type (FAS; BAS; AC) of the signaling information results from the position of this signaling information in blocks which are formed from the useful signal / signaling information words (NSW),
the useful signal / signaling information words (NSW) are transmitted in at least one useful data channel (B1, B2), while the hidden useful signal bits (LSB Io) of the least significance are separated from the useful signal / signaling information words (NSW) by the transmitting end device (T1 ) are transmitted to the receiving end device (T2) in the signaling channel (D); and
consisting of the following procedural steps, which are carried out at the receiving end,
from the transmitted useful signal / signaling information words (NSW), the signaling information bits (Ih) faded in on the transmission side are faded out and used for combining the useful data on the receiving side, and
in place of the hidden signaling bits (Ih) the useful signal bits (LSB Io) of the lowest value are faded in, so that the original useful data signal words (NW) are restored, and
the useful data signal words (NW) are decoded and then converted into analog signals. 2. Circuit arrangement for carrying out the method according to claim 1, characterized in that a ste device (TR) is provided on the transmission side,
which fades out at least the useful signal bit (LSB Io) of the lowest value from the useful signal words (NW), which fades in a signaling information bit (Ih) in place of the bit (LSB Io) of the lowest value and in this way the useful signal / Signali information information words (NSW) forms, the signaling information bits (Ih) form a predeterminable number of successive useful signal / signaling information words signaling words (SW), which in addition to frame alignment information (FAS) and bit rate assignment information (BAS) may contain further organizational information (AC) , where the type (FAS; BAS; AC) of the signaling information results from the position of this signaling information in blocks which are formed from the useful signal / signaling information words (NSW) and that a second device (RE) is provided on the receiving end is that of the transmitted useful signal / signal isie information words (NSW) fades out the signaling information bits (Ih) which are shown on the transmission side and is used to merge the user data on the receiving side, and
which fades in the useful signal bits (LSB Io) of the lowest value in place of the hidden signaling bits (Ih) so that the original useful data signal words (NW) are restored.