NO862762L - TIME MULTIPLE SYSTEM FOR TRANSMISSION OF VIDEO AND SMALL RAND SIGNALS. - Google Patents

Description

The invention relates to a digital time multiplex system for the transmission of video and narrowband signals as stated in the introductory part of patent claim 1.

With the introduction of integrated digital broadband networks, there are new requirements in terms of flexibility with regard to channel assignment and bitrate selection. The CCITT recommendation G 751 for the pulse frame that applies to the transmission of a 140 Mbit/s signal is not particularly suitable for the new broadband networks.

In DE-OS 32 30 943 instructions are given for a system which serves for the digital transmission of video and narrowband signals; and which has a pulse frame different from the CCITT recommendation. The pulse frame contains 2176 time slots of 10 bits each. Especially due to the width of the time slots and a frame frequency of 6.4 kHz, it becomes difficult to realize different channel types that mostly have a bitrate of 64 kbit/s or a multiple thereof - in some cases also only a bitrate of 32 kbit/s s or 16 kbit/s.

The task of the invention is to provide instructions for a digital time multiplex system which serves for the transmission of video and narrowband information and is suitable for the transmission of narrowband signals with different bit rates.

Starting from the known system indicated at the outset

this task is solved by the features that are specified as characteristic in patent claim 1.

In the time multiplex system according to the invention, both the width of a time slot of 8 bits and also the frame frequency of 8 kHz are favorable. By dividing it into four equal pulse subframes, narrowband channels are provided, each comprising two time slots (16 bits) in corresponding places of each time pulse frame.

In a narrowband channel, it is possible to e.g. to transfer the information with an audio channel with 16 x 32 kbit/s = 512 kbit/s. The sampling values in a narrowband channel are transmitted with sampling

the frequency (32 kHz) of the audio signal.

To make it possible to transmit signals with higher bit rates, several narrowband channels are combined. Likewise, it is conceivable to divide a narrowband channel into several subchannels.

In a time slot of a subchannel, a signal with a bitrate of 64 kbit/s can be transmitted at any time.

The transmission of the video signal takes place with the nominal bitrate of 135 Mbit/s. In each pulse frame, there are 24 bits for speed adaptation (filling), of which 18 bits are assigned to the filling information for a fillable time section comprising 6 bits,

i.e. three and three filling information bits per bit at the time section that can be filled in.

The invention will be explained in more detail by way of examples.

Fig. 1 shows a pulse frame with an octet structure.

Fig. 2 shows a variant of this pulse frame, and

fig. 3-5 illustrate different possibilities for coating the pulse frame's narrowband channels.

The connection-wise structure of time multiplex systems is sufficiently known. This description is therefore concerned with the structure of the pulse frame according to the invention and the various possibilities for utilizing existing narrowband channels for the transmission of narrowband information.

In fig. 1 shows an embodiment of the pulse frame according to the invention. It consists of four equally long partial pulse frames TR1-

TR4 each comprising 544 time slots each with 8 bits. By adding two successive time slots ZS1 and ZS2, ZS69 and ZS70-ZS477 and ZS478 in all sub-pulse frames, 8 narrowband channels SK1-SK8 are formed which are at equal distances from each other.

The pulse frame has a frame frequency of 8 kHz, and the transferable bitrate for the overall pulse frame is therefore obtained:

Each time slot in a pulse frame enables transmission with

a bitrate of 64 kbit/s, and for a narrowband channel the transfer rate is 8 x 64 kbit/s = 512 kbit/s.

In the first narrowband channel, a 10-bit long frame marking word RKW, a frame number RN is transmitted in each partial pulse frame

which includes two bitsy and four message bits MW. The narrowband ducts can be coated as desired. Thus, the narrowband channels are SK3

and SK7 in fig. 1 covered with each sound channel TK1 resp. TK2. As shown enlarged in the case of the audio channel TK2, 16 bits are assigned to a sampling frequency of an audio signal. The sampling value is coded with e.g. 14 signal bits, and in addition a parity bit P and a marking bit K are added to characterize the channel. The sampling frequency of the audio signal

of 32 kHz corresponds exactly to the frame frequency of the sub-pulse frames TR1-TR4, i.e. the frequency of a narrowband channel time slot.

For the transmission of a video signal, the time slots between the narrowband channels are available. The video signal is transmitted in the thus formed video channel BK with a nominal bitrate of

135 Mbit/s. In addition, for each pulse frame there are 24 bits for speed adaptation (padding) between the video signal to be transmitted and the pulse frame. 6 of these bits are thus used as fillable time sections, while the other 18 bits serve as fill information, three by three fill information bits being assigned to one fillable time section of one bit. If the video signal to be transmitted has exactly the bitrate of 135 Mbit/s, three of the fillable time sections (each 1 bit long) are coated with information bits. In order to be able to carry out the filling method flawlessly even in the case of disturbances to the transmitted signal, it is recommended to distribute the filling information evenly over the pulse frame.

In fig. 2 shows a variant of the pulse frame. The narrowband channels SK1-SK8 again comprise two time slots with 8 bits each, but not located next to each other, but evenly distributed over the sub-pulse frame. This structure is preferable when mainly narrowband information with low bit rates is transmitted, since at any time between two of the time slots of a partial pulse frame that serves for the transmission of narrowband information, an equally long processing time is available. Otherwise, the same considerations apply to this pulse frame as for the pulse frame in fig. 1. The following examples of covering the narrowband channels will therefore only be explained in more detail for the first described pulse frame.

At the pulse frame shown in fig. 3, the narrowband channels SK2, SK4, SK6 and SK8 are coated with a digital signal DS which exhibits a bitrate of 2.048 Mbit/s. The narrowband channels SK3 and SK7 again serve to transmit audio signals. A stereo sound signal can thus be transmitted in both narrowband channels.

The first time slot of 8 bits in the narrowband channel SK5 is used for the transmission of video text signals VT. Each time slot of a sub-pulse frame enables the transmission of a videotext signal of 64 kbit/s or the transmission of two conventional videotext signals of 32 kbit/s each. In the respective second time slot of the narrowband channel SK5, a so-called basic-access channel B+B+D is realized in the time slots of the first three partial pulse frames. The D-channel here only has a bitrate of 16 kbit/s,

and it thus occupies only two bits of the corresponding time slot of the third partial pulse frame.

The pulse frame shown in fig. 4, serves for transfer

of three stereo audio signals. The sound channels TK1 and TK2, TK3 and TK4 as well as TK5 and TK6 form one stereo channel. In the narrowband channel SK5, the video text signals and a basic access signal are transmitted.

The pulse frame shown in fig. 5, is coated with two audio channels TK1 and TK2 in the narrowband channels SK3 and SK7. The narrowband channels

SK2, SK4, SK5, SK6 and SK8 form a subscriber multiplex access channel consisting of one HO+D channel each. The HO channel has a bitrate of 384 kbit/s and the D channel; which is used for signaling, has a bitrate of 64 kbit/s. In this connection, one HO channel and one D channel can be realized within a narrowband channel. The unoccupied time slots in the narrowband channel serve as a reserve and can be occupied with additional narrowband information, e.g. a voice signal with 64 kbit/s.

In the pulse frames shown in fig. 3-5, it is of course not possible to show all existing and planned channel configurations■ and data interfaces - e.g. they only draft existing CCITT recommendations for the integrated data network ISDN to be realised. On the basis of the pulse frame frequency of 8 kHz, the time slot width of 8 bits and thus a bitrate of 64 kbit/s for each time slot and with a bitrate of 512 kbit/s per narrowband channel, however, allows all currently known data interfaces to be realized in a simple way.

Claims (9)

1. Digital time multiplex system for the transmission of video and narrowband signals with a bitrate of a total of 139.264 Mbit/s, where the video signal, which exhibits a nominal bitrate of 135 Mbit/s, associated filler signals, synchronization signals and narrowband signals which in particular have a bitrate of 64 kbit/s s or a multiple thereof, are summarized into a pulse frame, characterized by the fact that the pulse frame comprises 2176 time slots (ZS) with 8 bits each, that the pulse frame is divided into four equal sub-pulse frames (TR1-TR4), and that each sub-pulse frame is equally spaced exhibits narrowband channels (SK1-SK8) which for each partial pulse frame comprise a total of 16 time slots (ZS) and each are one or two time slots (ZS) wide, and which serve for the transmission of narrowband and synchronization signals. 2. Time multiplex system as specified in claim 1, characterized in that one narrowband channel (SK1, SK2 ... SK8) comprises two adjacent time slots. 3. Time multiplex system as specified in claim 1, characterized in that one and one narrowband channel comprise two and two time slots (ZS1 and ZS35; ZS 69 and ZS 103...) located at a mutual distance of 34 time slots. 4. Time multiplex system as specified in claim 2 or 3, characterized in that the first narrowband channel at the beginning of each partial pulse frame (TR1-TR4) is arranged for the transmission of synchronization signals. 5. Time multiplex system as specified in claim 4, characterized in that the synchronization signal comprises a frame marking word (RKW) comprising 10 bits, a frame number (RN) comprising 2 bits, as well as 4 message bits (MW). 6. Time multiplex system as specified in claim 1, characterized in that the narrowband channels (SK2-SK8) which do not serve for the transmission of synchronization information, can optionally be covered with audio signals, speech or data signals. 7. Time multiplex system as specified in claim 1 or 4, characterized in that the narrowband channels (SK2-SK8) are each divided into 8 subchannels with a bitrate of 64 kbit/s. 8. Time multiplex system as stated in claim 7, characterized in that several subchannels are combined for the transmission of signals with higher bit rates. 9. Time multiplex system as stated in claim 6, characterized in that several narrowband channels (SK2, SK4, SK6 and SK8) are combined for the transmission of data signals with higher bit rates.