CH675334A5 - - Google Patents

Description

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description

The invention relates to a method for forming and dissolving a multiplex according to the preamble of patent claim 1.

In the planned broadband communication network, called broadband ISDN, there is the problem at the subscriber line level of transmitting digital signals for different services of different bandwidth between a switch and the broadband connections in time division multiplexing via the respective subscriber line. These are signals from a so-called H4 channel for moving image transmission with a bit repetition rate of almost 140 Mbit / s, further signals from so-called H1 channels, each with a bit repetition frequency of 1920 kbit / s and possibly also signals from so-called H2 channels with each approximately 30 Mbit / s, furthermore signals from B channels, each with 64 kbit / s and the signaling channel D with a bit repetition frequency of 16 kbit / s. This transmission problem is described, for example, in ntz, vol. 39 (1986), issue 7, pp. 502 to 508, in particular image 4 and the associated description. The bit rate frequencies of the individual H channels H2, H3, H4 are not yet standardized.

A multiple xer / demultiplexer according to the preamble of claim 1 is known from DE-A1 3 509 363. Several H1 "signals are each filled with a bit repetition frequency of 1920 kbit / s to 2176 kbit / s and with an H4 signal with a bit repetition frequency of 136,000 kbit / s, which is filled up to 139,264 kbit / s The disadvantage of such a multiplex structure is that the existing bit sequence frequencies must first be increased to other bit sequence frequencies before they can be combined in time multiplex. This means that a considerable amount of circuitry is required in Form of buffers and Vormul-tiplexern is necessary and that a significant proportion of redundant bits is obtained in the pulse frame generated.

It is the object of the invention to specify a method for the formation and resolution of a multiplex through its pulse frame structure, which is suitable for several of the bit rate frequencies considered in the standardization discussion.

The object is achieved as indicated in claim 1. Further developments can be found in the dependent claims.

The invention will now be explained, for example, with reference to the drawings. Show it:

1 shows the frame structure of the method according to the invention with an occupancy by a 135 168 kbit / s H4 channel and a plurality of narrow-band channels,

2 shows the frame structure of the method according to the invention with the assignment of four 33 792 kb'rt / s H2 signals and several narrowband signals,

3a and 3b examples of the assignment of columns 1 to 34 of the frame structure of the method according to the invention for bit repetition frequencies of the European multiplex hierarchy, and

4 a and 4 b examples of the assignment of columns 1 to 34 of the frame structure of the method according to the invention for bit repetition frequencies of the North American multiplex hierarchy.

The frame structure of the method according to the invention will now be explained with reference to FIG. The smallest unit of the pulse frame is an 8-bit period, which is indicated in the upper left corner. Since the frame repetition frequency is 8 kHz, as in the DE-OS mentioned at the beginning, such a time segment represents a time channel with the transmission capacity of 64 kbit / s. The frame now has 390 columns and 6 rows, ie 390 x 6 = 2340 time segments with each 8 bits. It follows from this that the output bit repetition rate of the multiplexer 149 is 760 kbit / s. This bit repetition frequency has the advantage that it exactly matches the bit repetition frequency of the OC3 hierarchy of the American “SONET” system.

A very favorable assignment of the pulse frame is that 352 columns are used to transmit an H4 broadband signal with a bit repetition rate of 135 168 Ibit / s and the remaining 38 columns, whose transmission capacity is 384 kbit / s each, for the transmission of several narrowband Digital signals, as will be explained, are used.

1 shows that the 352 columns 39 to 390 of the pulse frame are occupied with the H4 signal with the bit repetition frequency of 135 168 kbit / s. With this assignment of the pulse frame, the transmission capacity of the broadband time channel formed by 352 columns is used exactly for the transmission of the 135 168 kbit / s H4 signal. This bit rate is one of the bit rates currently under discussion for the transmission of the moving picture signal in the subscriber line area.

In an advantageous embodiment of the invention, columns 1 to 38 of the pulse frame shown in FIG. 1 are occupied as follows: Columns 35 to 38 are used to transmit a signal NOH4 assigned to signal H4 with a bit repetition frequency of 1536 kbit / s. This signal contains control and synchronization signals for monitoring the transmission of the H4 signal and is also called "network overhead". Together with the H4 signal, it forms a C4 signal with the bit repetition frequency 136 704 kbit / s. Columns 1 to 5 form a time channel with a transmission capacity of 1920 kbit / s, in which additional frame information for system monitoring and synchronization and possibly one or more D signals with the bit repetition rate of 16 or 64 kbit / s can be transmitted.

Columns 6 to 10 also form a time channel with the transmission capacity of 1920 kbit / s, in which, for example, signals from up to 30 B channels can be transmitted with a bit repetition frequency of 64 kbit / s each.

Columns 11 to 34 are expedient

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used to transmit signals from so-called H1 "channels or C1 channels, a C1 signal consisting of an H1 signal and an additional signal associated with this signal for the transmission of synchronization, control information or the like.

As will be explained with reference to FIGS. 3 and 4, the pulse frame of the method according to the invention has the advantage that it is used both for the bit repetition frequencies provided in the European hierarchy H12 = 1920 kbit / s, C12 = 2048 kbit / s and for the bit repetition frequencies North American multiplex hierarchy H11 = 1536 kbit / s, C11 = 1920 kbit / s is particularly suitable.

2 shows an example of an advantageous allocation of the pulse frame of the method according to the invention, in which the 356 columns with the numbers 35 to 390 form four H2 broadband time channels with a transmission capacity of 33 772 kbit / s each. If it is necessary to transmit additional information (“network overhead”) for each of these four time channels, the columns that immediately precede those used to form the channel, that is to say column 35 for, can be used for this purpose, as shown the H2 time channel formed from columns 36 to 123, column 124 for the H2 time channel formed from columns 125 to 212, column 213 for the H2 time channel formed from columns 214 to 301 and column 302 for the columns 303 to 390 formed H2 time channel. Each of these four columns, together with the columns for the associated H2 time channel, forms a so-called C2 time channel, the transmission capacity of which is 34 176 kbit / s.

An example of the already mentioned assignment of columns 1 to 34 of the pulse frame is now given with reference to FIGS. 3a and b. The prerequisite is that the bit rate of the narrow-band time channels is H12 = 1920 kbit / s in accordance with the European multiplex hierarchy.

In Fig.3a, columns 1 to 10 are occupied as in Fig.1. Of the remaining columns 11 to 34, 5 are used in each case to form a time channel whose transmission capacity is exactly equal to H12. The remaining 4 columns 31 to 34 can be used to form any other time channels and have a total transmission capacity of 1536 kbit / s. In the event that so-called C12 signals are to be transmitted instead of the H12 signals with 1920 kbit / s each, i.e. the information from the H12 channels plus additional information, the bit rate of 2048 kbit / s would be suitable for this, which is the bit rate of the first level PCM hierarchy. For the transmission of such a C12 signal, as shown in FIG. 3b, 6 columns of the pulse frame can be combined to form a time channel with the transmission capacity of 2304 kbit / s. This bit rate is the same as that of C12 as 9: 8. C12 can thus be transmitted in this time channel in such a way that every 9th of the total of 36 time slots remains free or is otherwise used.

3b shows that columns 12 to 34 can be used for four such C12 narrowband time channels. Columns 6 to 10 can form 30 B time channels, each with a transmission capacity of 64 kbit / s.

4a and 4b show an example of the assignment of columns 1 to 34 of the pulse frame, which is adapted to the bit rate H11 = 1536 kbit / s, which occurs in the North American multiplex hierarchy. In this example, 4 columns form a narrowband time channel, the transmission capacity of which is exactly the same as the bit rate of 1536 kbit / s. If only 4 such narrowband signals H11 are to be transmitted, this can, as shown in FIG. 4a, take place in columns 6 to 9, 10 to 13, 14 to 17 and 18 to 21, and the remaining columns 22 to 34 mean free transmission capacity for any channels.

In the event that not the H11 signal with 1536 kbit / s, but a so-called C11 signal, consisting of the H11 signal and signals for transmitting additional information, is to be transmitted, its bit rate could be equal to 1920 kbit / s, and such a C11 signal could then be transmitted in a time channel formed from 5 columns with exactly the same transmission capacity as is shown in FIG. 4b with columns 6 to 10, 11 to 15, 16 to 20 and 21 to 25, and Columns 26 through 34 could, if only four C11 signals are required, be used as free transmission capacities for any other narrow band signals.

It is readily apparent from FIGS. 3a and b and 4a and b that the pulse frame of the method according to the invention excellently with the bit rate frequencies already standardized for the narrowband time channel H12 of the European hierarchy and also for the narrowband time channel H11 of the North American multiplex hierarchy suitable is.

Another advantage is that with columns 1 to 10 there is sufficient transmission capacity totaling 3840 kbit / s to transmit the required additional frame information (“overhead”) and D and B signals.

Finally, the invention has the great advantage that it is not only suitable for a system which has a fixed transmission capacity for each of the services, but also for a system with asynchronous time division multiplexing ("Asynchronous Time Division" = ATD), in which the information to be transmitted for a service is combined in packets.

Because of the additional control information required for this purpose, a transmission capacity of 143 616 kbit / s (= 135 168 x 17/16) is required in order to transmit a signal which corresponds in its useful information content to an H4 signal. For this signal with the bit repetition frequency of 143 616 kbit / s, 374 columns can be provided in the pulse frame, and with 16 columns there is still enough transmission capacity left for the narrowband signals and the additional frame information.

The same applies to the transmission of a signal that contains one in its useful information

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C4 signal corresponds. A bit repetition rate of 145 248 kbit / s is required for this signal, for which 380 columns can be provided in the pulse frame. With 10 columns there is still enough transmission capacity left for the narrowband signals and the additional frame information.

Claims (11)

Claims 1. A method for the formation and resolution of a time multiplexer for the transmission of digital signals of various services, in particular via a subscriber line, the frame repetition frequency of the pulse frame being 8 kHz, characterized in that the pulse frame consists of 390 columns and 6 rows, the 2340 time segments with 8 each Form bits. 2. The method according to claim 1, characterized in that 352 columns (39 to 390) form a broadband time channel with a transmission capacity of 135 168 kbit / s and that 38 columns (1 to 38) form time channels, the transmission capacity of each integer multiple of the transmission capacity of a column of 384 kbit / s is (Fig. 1). 3. The method according to claim 2, characterized in that additional information (NOH4) for the broadband time channel (H4) is transmitted in a narrow-band time channel (35 to 38) formed from 4 of the 38 columns, so that these four columns together with the 352 columns form a broadband time channel (C4) with a transmission capacity of 136 704 kbit / s (Fig. 1). 4. The method according to claim 3, characterized in that the 356 columns (35 to 390) follow one another directly within the pulse frame. 5. The method according to claim 1, characterized in that four groups of 88 columns (36 to 123,125 to 212, 214 to 301, 303 to 390) four broadband time channels (H2) with a transmission capacity of 33 792 kbit / s each form, and that 38 columns (1 to 39, 35, 124, 213, 302) form time channels, the transmission capacity of which is an integer multiple of the transmission capacity of a column of 384 kbit / s (Fig. 2). 6. The method according to claim 5, characterized in that in four narrowband time channels (HOH2), each of which is formed from one (135, 124, 213, 302) of the 38 columns, additional information (HOH2) for each of the four broadband time channels (H2) is transmitted, so that 88 columns forming the broadband time channel (H2) (36 to 123.125 to 212.214 to 301.303 to 390) together with a column forming the associated narrowband time channel (NOH2) (35 , 124, 213, 302) form a broadband time channel (C2) with a transmission capacity of 34 176 kbit / s (FIG. 2). 7. The method according to claim 6, characterized in that the 89 columns forming the broadband time channel (C2) follow one another directly in the pulse frame (FIG. 4). 8. The method according to any one of the preceding claims, characterized in that within the 38 columns groups of four columns or groups of five columns or groups of six Columns or combinations of such groups are included, a group of four columns a narrowband time channel with a transmission capacity of 1536 kbit / s, a group of five columns a narrowband time channel with a transmission capacity of 1920 kbit / s and a group of six Columns forms a narrowband time channel with a transmission capacity of 2304 kbit / s. 9. The method according to claim 8, characterized in that in each of the narrow-band time channels formed from four columns with the transmission capacity of 1536 kbit / s, an H11 signal is transmitted at 1536 kbit / s (Fig.4a). 10. The method according to claim 9, characterized in that in a narrow-band time channel formed from five columns with the transmission capacity of 1920 kbit / s, an H12 signal with 1920 kbit / s (Fig.5a) or with an H11 signal 1536 kbit / s and additional information composed C11 signal (Fig. 6) with 1920 kbit / s or 30 B signals with 64 kbit / s each are transmitted (Fig.3a, Fig.4b). 11. The method according to claim 8, characterized in that in a narrow-band time channel formed from five columns with the transmission capacity of 2304 kbit / s, an additional signal for transmission monitoring purposes and further signals or an H12 signal with 1920 kbit / s s and additional information composite C12 signal with 2048 kbit / s (Fig. 5b) is transmitted (Fig. 3b). 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th