NO155220B - PROCEDURE FOR AA TO INCLUDE A DATA FLOW IN THE FIELD OF TRANSFER. - Google Patents

Abstract

1. A method of integrating a binary clock-pulse-driven or non-clock-pulse-driven data flow (B) of low bit rate (e.g. a service conductor data flow), which preferably serves for the transmission of data commands and control commands and measured values, into a main data flow (H) of high bit rate with two radiation power levels, which is conducted via a light waveguide transmission link without metallic auxiliary wires, where the data flow (D) of low bit rate is combined with the main data flow (H) in a drive electronic unit (5) at the transmitting end to form a transmission data flow (U) with three radiation power levels, where at the receiving end a decision device - which responds to the first two levels - for the main data flow (H) and a second decision device - which responds only to the third level - for the data flow (D) having the low bit rate are driven in parallel, characterised in that the combination of main data flow (H) and low rate data flow (D) is carried out in the drive electronic unit (5) for the transmitter (1) by changing the supply voltage of the drive electronic unit (5) in the timing of the low bit rate data flow (D) and that here the main data flow does not contain long zero sequences.

Description

The invention relates to a method for incorporating a data stream into optical fiber transmission lines as stated in the introduction of the main claim.

During assembly or when troubleshooting, it is necessary to connect service cable paths via a special cable to be used for assistance, or an already existing cable. In the case of transmission lines carried over cables with metallic conductors, the service line path can be routed over these metallic conductors. In the case of transmissions over optical fiber cables without metallic accessories, this possibility disappears.

Therefore, in many cases, a separate cable with metallic conductors is laid out, over which the service line is then routed. However, this method is very time-consuming and expensive.

DE-AS 29 13 924 describes a remote cable system

which without great expense, above all without additional cable, provides the opportunity to transmit low-frequency additional information. In contrast to the method according to the present invention, however, the additional information is not permanently linked with the main information for transmission purposes. Instead, an auxiliary frequency is derived from the main information for the transmission of the additional information.

In the proposal according to DE-AS 29 13 924, however, it is also unfortunate that a free transmission channel is required for the transmission of the additional information.

From Japanese Patent Abstract No. 56-13850 in conjunction

with JP-A-5613850 there is known a system which is carried out in accordance with the preamble of patent claim 1 and serves for the transmission of digital signals, and where a data stream with a lower bitrate is combined with a main data stream with a relatively high bitrate with two radiation levels. The transmission data stream with three radiation power levels is carried over an optical waveguide transmission path without metallic accompanying conductors to the receiving side. On the receiving side, there is, in addition to a decision link for the main data flow, arranged to react to

the first two levels, paralleled a further decision stage for the added data stream, arranged to respond only to the third level.

The task that forms the basis of the invention, and which consists in using transmission lines that are carried on light waveguide cables without metallic accessories, while simultaneously transmitting a data stream (e.g. service line data stream) in addition, is solved according to the invention with the characterizing features according to the main requirement.

Advantageous further designs of the invention

is stated in the sub-requirements.

The advantage that can be achieved with the invention consists in particular

in that in the case of service cable routes that are carried over optical waveguide cables without metallic accessories, it is not necessary to lay out any separate cable with metallic conductors. All cables remain reserved for public communication traffic, and the service cable routes are nevertheless integrated into the system. This avoids unnecessary costs.

Furthermore, it is advantageous that when using the method according to the invention in PCM systems, nothing is changed about the CCITT frame structures for the PCM multiplex operation. Furthermore, it is advantageous that a service cable route which is provided in accordance with the invention and is not needed, by using known devices, can additionally be used for automatic monitoring of the section.

The invention will be explained in more detail below

an embodiment which is visualized in fig. 1 and 2.

Fig. 1 shows a block switching core with pulse diagram.

Fig. 2 shows a coding and decoding table.

More specifically, fig. let the block connection diagram for an embodiment of the object of the invention and fig. lb the corresponding pulse diagrams at "return to zero" (RZ). However, the invention is also applicable when working with "non return to zero" (NRZ).

A transmitter 1 is controlled by a control electronics 5 with two inputs. In this electronics, a main data stream H and a data stream D are combined into a transfer data stream U. The summary takes place according to the invention so that the pulses in the transfer data stream U assume a further (e.g. third) radiation power level when pulses in both data streams occur

simultaneous. In the electrical part, it is about electrical level

and in the optical part about radiation power level).

For this purpose, the control electronics 5 are equipped with

another input 4 for the data stream D. In summary-

The connection between the main data stream H and data stream D consists, according to the invention, in that the supply voltage for the control electronics 5 or for a suitable part of the connection is increased in time with the data stream D. This results in the fact that a pulse of the main data stream 'always occurs, in the case of a simultaneously occurring pulse of the data stream D at the input 4 of the control electronics 5 is changed (as a rule raised) with respect to the voltage level. "L" pulses of the data stream D can therefore only be transmitted when there are "L" pulses in the main stream H which are changed with respect to voltage levels with the help of the data stream D. This is illustrated in the coding table in fig. 2a. On the other hand, this option for transfer exists when using the MBNB code always for the main data stream H, as this due to the higher bit rate is significantly higher in frequency than the data stream D. Also when using a scrambler, a longer sequence of zeros is also most likely excluded.

The transmission data stream t) which is generated in the control electronics 5 is converted in the transmitter 1 into a sequence of corresponding radiation pulses with different power levels and delivered on the light waveguide cable.

On the receiving side, a receiver 6 delivers the transmission data stream 0 in parallel to a first decision link 2 for the main data stream H and to a second decision link 3 for the data stream D.

The first decision link 2 for the main data stream H delivers an "L" (fig. 2b) whenever the absolute value of a first voltage level at the output of the receiver 6 is a certain value different from zero (level 1) and thus exceeds the decision threshold; this is independent of whether there is only a signal from the main data stream H (level 1) at the control electronics 5 or, in addition, a signal from the data stream D

(Level 2).

The second decision link 3 for the data stream 3 delivers a

"L" always when the absolute value of the second voltage level at the output of the receiver 6 is different from zero and absolute

calculated is greater than the absolute value of the first voltage level and exceeds the corresponding decision threshold for the decision link 3. The length of the pulses emitted by the second decision link 3 for the data stream D corresponds approximately to the length of the pulses of the main data stream H. The length of the pulses of the data stream D is, however, due to the much lower bit rate much greater than that of the main data stream H. Thus, the pulses emitted by second decision link 3 must be extended to the original length of the pulses of data stream D. This is achieved with a monostable multivibrator 7 connected to second decision link 3. Further in - hitting threshold exceedances with the highest level 2, fig. 2b, which occurs during this pulse extension, does not trigger any unstable states of the monostable multivibrator 7.

As a result of the very long pulses of the data stream D, their exact beginning does not matter so much as long as the main data stream H does not have too long a zero sequence. In the event that the method is used in a PCM system that transmits the main data stream, the beginning and end of a word can be defined from the data stream D by means of the frame marking words contained in the main data stream H, or one defines for some successive words in the data stream D a own frame marker word. The latter method has the advantage over the former that the data stream D is transmitted regardless of the errors even in the event of an error-ridden transmission of the main data stream H.

Claims (3)

1. Method of incorporating a clocked or unclocked binary data stream (B) (e.g. service line data stream) which has a low bitrate and preferably serves for the transmission of data and control commands as well as measurement values, into a main data stream (H) which has a higher bit rate and two radiation power levels, and which is carried over an optical waveguide transmission path without added metallic conductors, comprising a control electronics (5) on the transmission side to combine the data stream (D) with a low bitrate and the main data stream (H) into a transmission data stream (U) with three radiation effect levels, during which a decision section responding to the first two levels for the main data stream (H) and a second decision section responding to the third level for the data stream (D) with a low bitrate are controlled in parallel on the receiving side, characterized in that the summation of the main data stream (H) and data stream ( D) with low bitrate in the control electronics (5) for the transmitter (1) occurs by changing the supply voltage of the control electronics (5) in step with the data stream (D) with low bitrate, and that the main data stream below does not show any longer zero sequences. 2. Method as stated in claim 1, characterized in that the frame marking word which is contained in the main data stream during transmission of the main data stream in a PCM system serves to determine the beginning and end of the words in the data stream (D) with a low bitrate. 3. Method as stated in claim 1, characterized in that a certain number of words in the data stream (D) with low bitrate is supplemented with an additional frame marking word.