FR2522908A1 - Modification system for information on service channel - uses coding and logic gating circuit to inject data onto transmission channel - Google Patents

Abstract

At an intermediate station the transmission channel enters a regeneration circuit which also recovers the timing. The clock and information signals are applied to a sync. pattern search circuit controlled by a time base. The time base and sync. signals are applied to an extraction circuit together with the information signal to recover the service channel information. The service information is decoded and modified as required and the signal is then recoded for application to a logic gating circuit for re-injection onto the information transmission frame by replacing the preceding characters. The gating circuit output is transmitted onto the transmission channel using the recovered clock signal.

Description

METHOD FOR TRANSMITTING A SERVICE ROUTE,
COULD BE MODIFIED DURING TRANSMISSION,
TRANSMITTER AND RECEIVER FOR IMPLEMENTING
OF SUCH A METHOD
The present invention relates to the field of information flow transmission, for example initially in binary form; it more particularly relates to the transmission of a service channel simultaneously with this information, and whose content is likely to be changed during transmission. It also relates to a transmitter and a receiver for the implementation of such a method.

 A binary information stream, which already represents an encoding of the information, generally requires a second coding, or transcoding, into a stream of pulses better adapted to the usual transmission media (cables with metallic conductors, optical fiber cables , radio links, etc.). The problem posed by such a transcoding has been the subject of numerous studies, among which may be mentioned by way of example an article by J.VALIN, published in the technical journal THOMSON-CSF (Volume 2, No. 2 - June 1979 , page 359). It emerges in particular that among the characteristics sought for a code, there is the minimization of the bandwidth normally necessary to transmit the signal correctly and the suppression of the DC component, so as to allow the simplification of certain elements of the transmission system. , and more generally the reduction of the bandwidth used towards the low frequencies. A number of complex codes are particularly known, described in particular in the aforementioned article, such as ternary codes (using three different symbols), quaternaries (four symbols), etc. for which the number of possible combinations is greater than that of the code (usually binary) of departure. This redundancy makes it possible to choose the value of the complex code which corresponds to each value of the start code according to a certain number of criteria, among which that of the current numerical sum. It is recalled that the latter is the sum of the values of the symbols of the complex code between the instant chosen as the origin of the emission and an instant t any.Or it is known that the demarcation of the numerical sum makes it possible in particular to eliminate the component Continuous signal transmitted: the value of the complex code is therefore generally chosen to reduce the current numerical sum.

 There is also the problem of the necessity of transmission, together with the main information, of a certain number of ancillary signals such as operating signals of the transmission channel, service telephone signals or for example, which together is what is generally called service channel or way of order.This service channel can be transmitted on an ancillary transmission path, but it is obviously preferable to transmit it on the same way as informatior. nrincipale. In the latter case, it is desirable that the transmission of this service channel does not significantly disturb the characteristics of the information transmitted and in particular its frequency spectrum and its low frequency components. Various solutions to this problem are known, for example described in French Patent No. 801670t in the name of LTT, but these known solutions generally do not allow to extract and reinject signals into the service channel without disturbing the information, or without oblige-er- to decode and then recode, which is practically possible at the ends of the transmission path. However, it is desirable to be able to use the service channel along the transmission path and in particular at intermediate stations containing repeaters and regenerators, which extend along this path.

 The present invention relates to a method ensuring the transmission of a service road and responding to the various requirements mentioned above, in particular to extract the service road, possibly change it and then reinject it during transmission without requiring a decoding (and then recoding) the information.

 More precisely, the subject of the invention is a method of transmitting a service channel simultaneously with information coded on a transmission channel, in which the information is coded in the form of words, each word comprises a predefined number of characters, the words being gathered in frames, each frame further comprising, in a predefined rank, at least one character assigned to the service channel.

Other features and advantages of the invention will emerge clearly from the following description, given by way of non-limiting example and illustrated with the aid of the appended figures, which represent:
FIG. 1, the general diagram of an embodiment of a transmitter implementing the method according to the invention;
- Figure 2, the general diagram of an embodiment of a receiver implementing the method according to the invention;
- Figure 3, the general diagram of an embodiment of the extraction and reinsertion of the service channel being transmitted information, for example in an intermediate station.

 In these different figures, the same references refer to similar elements.

 In the diagram of Figure 1, there is shown the insertion of the service channel after transcoding of the information to be transmitted, made in the transmitter according to the invention.

 The transmitter of FIG. 1 thus receives, on the one hand, the information to be transmitted, denoted IB, as well as a clock signal H, transmitted to a time base BTE which ensures the synchronization of all the operations performed. by the issuer. IB information is generally provided in serial binary form; it is converted in parallel form by means of a serial-parallel converter C5p under control of the time base BTE. then provided to a CI encoder which transcodes the information la so, as mentioned above, to make it more suitable for the transmission path. Such a transcoding is for example here of the form 5B / 6B that is, it transforms binary information Ig expressed in 5-bit words into information written IT, also binary but expressed in words of 6 bits. The encoder CI also realizes the grouping of the words constituting the information la in frames, that is to say in sets of M words, M being generally constant from one frame to another, and each frame starting with one particular synchronization signal, called synchronization pattern or frame-locking word (VT) .The CI-encoder here makes each frame so that a space corresponding to the duration of the frame is left available in a predefined row of the frame. service channel that is intended to transmit with the frame, all being synchronized by the time base BTE.

 The signals (VS) constituting the service channel are coded, in an encoder marked VS 'so as to disturb at least the type 6B frames provided by the encoder C1, according to criteria described below. The coded service channel is denoted 1VS and it is supplied to means I, which also receive the IT frames provided by the coder CI, the means I realize, under control of the time base BTE, the insertion of the information IVS at the free spot in the IT frame. In the example shown, the service channel is constituted by an integer word of 6 bits, which is inserted for example substantially in the middle of the frame, which facilitates recovery of the clock signal on reception; by way of example always, the frame comprises from 250 to 1000 words of 6 bits.

 The information provided by the means I, thus comprising the transcoded information and the service channel, denoted ITVT ', is converted into serial form by a parallel-serial converter CPS and then supplied to an emitter E which ensures its transmission on the channel of transmission V, the elements CPS and E being also controlled by the time base BTE.

 FIG. 2 represents an embodiment of a receiver according to the invention.

The receiver receives from the transmission path V a signal which it must first regenerate and in which it is necessary to recover the rhythm, which is done conventionally by means marked RR in the diagram and which provide, on the one hand, - the previous ITVS information in serial form and, on the other hand, the H 'tpmme to a reception time base denoted BTR. The ITVS information is converted into a parallel signal by a CSP converter, in relation to RVT search means of the synchronization pattern VT, in order to properly perform the cutting into words of the received message, interacting with the time base BTR. ITVS parallel information is transmitted to means E ensuring the extraction of the service channel, which is recalled that we know the position in the frame, and thus separately provides information IVS and 1T
The IVS information is supplied to a DVS decoder which makes it possible to retrieve, from their binary coding (IVS), the auxiliary signals (VS) constituting the service channel.

 The information IT is transmitted to a decoder D1 operating the inverse transcoding of the encoder CI of FIG. 1, that is to say of the type 6B / 5B in the example chosen, and at the same time eliminating the division into frames. . The signal obtained is the initial binary IB information in parallel form which, after passing through a parallel CPS series converter, is available in serial form.

 The set of elements E, D1 and CPS is synchronized by the time base BTR, which further provides the clock signal H.

 FIG. 3 illustrates an embodiment of an intermediate station on the transmission path, this type of station generally having the function of regenerating the transmitted signal.

 This station therefore receives the transmission path V which leads to a regenerator and RR rate recovery, similar to that of Figure 2 and which therefore delivers on the one hand the ITVS information and secondly the rhythm H '.

Unlike the case of the receiver of FIG. 2, the ITVS information is not decoded here; The extraction of the service road is substantially as in Figure 2 using means E controlled by a BT time base and RVT means of
search for VT synchronization pattern; in the embodiment shown, the ITVS information is in serial form but it is of course possible to carry out this research on an infor-
given in parallel form. The means E therefore provide
1V5 information that is transmitted to a DVS decoder providing VS signals constituting the service channel.These can after
possible modifications transforming them into VS 'signals, be reinserted in the message via a Cvs encoder similar to that of Figure 1 and, for example, using a logic circuit L controlled by the time base BT, receiving both the information 1TVS and the information 1V5 'The circuit L is constituted
by a first logic gate to an input and two outputs, the input
receiving from the time base BT an insertion order of the service channel in the frame, which is for example in positive logic, that is to say equal to I when there is modification of this service channel; one of the outputs of the gate L1 is without inversion and transmits the previous order without modification to a logic gate L2 of the type
NOR, which provides the complement of the information 1TVS - only when the previous insertion command is at zero, towards a third logic gate, denoted L3, of the NOR type.

The second output of the gate L1 is inverting and transmits the complement of the previous order to a fourth logic gate, denoted L4 and of type NO, which receives by. Elsewhere the modified service channel 1V5 'The door L4 transmits the complement of only when the previous order is at 1, towards the door L3. The latter thus provides a frame comprising either
the old service channel (ITyS)> is the new one, the frame then being noted as ITVs, as a function of the value of the insertion order.

The circuit L therefore provides ITVS information, or ITVS to
emitter E, similar to that of FIG.
the signal H 'and transmits the set on the transmission path V.

It has been described in the preceding figures a service road
(IVS) formed by an integer word of the code used on the transmission path. Of course, different solutions are possible and the service path may represent only one character of this code or, conversely, several words. However, in order not to modify the frequency spectrum of the transmitted signal particularly at low frequency, and to allow the extraction and possibly the modification of this service channel at any point in the transmission path, without decoding and recoding, it is desirable that the numerical sum of the characters assigned to the service road is predetermined, so, in case of modification, to replace them with characters of the same sum; in a preferred embodiment, this sum is zero. To meet these requirements, two solutions are possible:
- First solution:
Correspond to a logical "1" on the service channel a group of characters whose sum is determined or preferably zero, and to a logical "0", another group of characters of sum also determined or zero, whose length can be the same or different. In this way, in the previous example, where a 6-bit word is available for the service channel (they), it is possible to transmit three signals (VS) on the service channel, each of which can take two values.

- Second solution:
When it is desired to transmit more service channel signals for a given number of characters, it is possible to match each possible combination of service signals (VS) with a set of characters or a word (IVS) of a fixed or zero sum. : as many combinations of service signals are needed. This solution can make it possible to transmit more service signals but entails a greater complexity since the signals in a service channel are not then independent of each other and to modify one of them, for example at an intermediate station such as that of Figure 3, it is then necessary to take into account other signals.

By way of example, for a binary information that undergoes a transcoding of the mB / nB type, the solution n 1 with zero digital sum leads to the following correspondence:
"0" logic (VS) # - + (IVS)
"I" logic (VS) # ± (IVS)
In the case of the SB / 6B code illustrated in the figures, taking an integer inteot (6 bits) for the service channel, three binary signals can be transmitted on each frame by means of the following correspondence table.

VS <SEP> IVS
<tb> ler <SEP> signal <SEP> 2nd <SEP> signal <SEP> 3rd <SEP> signal <SEP> ler <SEP> signal <SEP> 2nd <SEP> signal <SEP> 3rd <SEP> signal
<tb> 0 <SEP> 0 <SEP> 0 <SEP> - + <SEP> - + <SEP> - +
<tb> 0 <SEP> 0 <SEP> 1 <SEP> - + <SEP> - + <SEP> +0 <SEP> 1 <SEP> 0 <SEP> - + <SEP> ± <SEP> - +
<tb> 0 <SEP> 1 <SEP> 1 <SEP> - + <SEP> ± <SEP> +1 <SEP> 0 <SEP> 0 <SEP> ± <SEP> - + <SEP> - +
<tb> 1 <SEP> 0 <SEP> 1 <SEP> ± <SEP> - + <SEP> +1 <SEP> 1 <SEP> 0 <SEP> ± <SEP> ± <SEP> - +
<tb> 1 <SEP> 1 <SEP> 1 <SEP> ± <SEP> ± <SEP> +
With the help of this same code 5B / 6B, and always in the case where a zero numerical sum is desired, the solution. No. 2 makes it possible to transmit four service channel signals per frame: in fact, there exists in this code 20 zero-sum words from which 16 are chosen to correspond to the 16 possible combinations of the service signals.

According to another example, always for a zero digital sum, when the transcoding is of the type mB / nT, that is to say that the binary information expressed on m bits is transcoded into a ternary information expressed on n ternary characters ( that is to say each of them can take one of the following three values: 1, 0, +1), the solution n I can be for example the following:

<SEP>"0"<SEP> logical <SEP>#<SEP> -1 <SEP> +1
<tb><SEP> VS <SEP>#<SEP><SEP>#<SEP> IVS
<tb>"1"<SEP> logical <SEP>#<SEP><SEP> +1 <SEP> -1
<Tb>
It thus appears that the numerical sum of the combinations of
O and 1 forming VS, transcoded in ternary, is necessarily null.
If, for example, a 6B / 4T transcoding is used, taking as before a complete word for the service channel, two service signals per frame can still be transmitted according to the solution n 1, as shown in the table below.

<Tb>

<SEP> VS <SEP> IVS
<tb> ler <SEP> signal <SEP> 2nd <SEP> signal <SEP> ler <SEP> signal <SEP> 2nd <SEP> signal
<tb><SEP> 0 <SEP> 0 <SEP> -1 <SEP> +1 <SEP> -1 <SEP> +1
<tb><SEP> O <SEP>: <SEP><SEP> 1 <SEP>: <SEP> -1 <SEP> +1 <SEP>: <SEP> +1 <SEP> -1
<tb><SEP> 1 <SEP>: <SEP> 0 <SEP>: <SEP> +1 <SEP> -1 <SEP>: <SEP> -1 <SEP> +1
<tb><SEP> 1 <SEP>: <SEP> 1 <SEP>: <SEP> +1 <SEP> -1 <SEP>: <SEP> +1 <SEP> -1 <SEP>
<Tb>
With the same code 6B / 4T, the solution n 2 makes it possible to transmit four service channel signals per frame because there are 19 words of zero sum, which makes it possible to choose the 16 combinations necessary for the four signals.

In the above transcoding examples, the information transmitted on the transmission channel is grouped into words comprising an even number of characters (6B from transcoding 3B / 6B or 4T resulting from transcoding 6B / 4T). In the case where these words contain an odd number of characters and if it is desired to introduce for the service channel only words of zero numerical sum, it is necessary to provide special provisions:
for transcoding of the type nB / mT (odd m), only ml characters are varied, the last being permanently zero, in order to find an even configuration;
for a transcoding of the type nB / mB (odd m), the word can not be of zero sum, it is the numerical sum preceding the service channel word which determines the value of the binary character. For example, for a transcoding 2B / 3B, we have:

<tb> sum <SEP> numeric <SEP> VS <SEP> IVS
<tb><SEP>> 0 <SEP> 0 <SEP><SEP>.<SEP> - <SEP> + <SEP>
<tb><SEP><0<SEP> 0 <SEP> + <SEP> - <SEP> +
<tb><SEP>> 0 <SEP>: <SEP><SEP> 1 <SEP><SEP>.<SEP> + <SEP> - <SEP>
<tb><SEP><0<SEP>:<SEP><SEP> 1 <SEP>: <SEP> + <SEP> + <SEP> - <SEP>
<Tb>
The above examples have been given for service channels using zero numeric sum words. It is also possible for this purpose to use non-zero sum words, for example of sum + Sn or -Sn according to the digital sum of the bit stream before the insertion of this service word. In this case, when one wishes, in intermediary stations, modify the service information, you must insert a word of the same amount as the one that was extracted.

 We give below an example with a numerical code 6B / 4T and non-zero sum words (here +2 or -2).

In the transmitter:

<tb> Sum <SEP> numeric <SEP> VS <SEP> IVS
<tb><SEP><0<SEP> 0 <SEP> ++ 00
<tb><SEP>> 0 <SEP> 0 <SEP> --00
<tb><SEP><0<SEP> 1 <SEP> 00 ++
<tb><SEP>> 0 <SEP> 1 <SEP> 00-
In an intermediate station:
- if we want to place a "0", we must issue ++ 00 if the word that we replace is positive sum and -00 if the word that we replace is negative sum;
- if we want to place a Hl ", we must issue 0O ++ if the word that we replace is positive sum and 00- if the word that we replace is negative sum.

It follows from the description made above that the introduction of the service channel in the transcoded information does not add a DC component to the spectrum of the transmitted signal; moreover, it modifies only very little this spectrum, by a slight enlargement due to the addition of one or more additional characters. Finally,
The extraction and insertion of signals in this service channel is easy, without decoding or recoding the main information transmitted.

Claims (5)

 A method of transmitting a service channel simultaneity with information encoded on a transmission channel, characterized in that the information is coded in the form of words, each word comprising a predefined number of characters, the words when they are combined into frames, each frame also comprises, in a predefined rank, at least one character assigned to the service channel.  2. Method according to claim 1, characterized in that each frame comprises a word assigned to the service channel.  A method according to one of the preceding claims, characterized in that the set of characters assigned to the service channel generally has a predetermined numerical sum.  4. Method according to claim 3, characterized in that the predetermined value of the numerical sum is zero.  Transmitter for implementing the method according to one of the preceding claims, characterized in that it comprises:  first coding means (Cvs) for the signals to be transmitted on the service channel;  second means (C1) encoding the information to be transmitted on the transmission channel and forming a frame with a space, in a predefined rank, corresponding to the duration of the set of characters assigned to the transmission channel; service;  third means for inserting (I) the information provided by the second means (case) into said predefined rank of the frame formed by the information provided by the first means;  fourth means (E) for transmitting the information provided by the third means.  Receiver for the implementation of the method according to one of claims I to 4, characterized in that it comprises:  first reception means (RR, CSP, RVT) of the transmitted information;  second extraction means (E) of all the characters assigned to the service channel;  third decoding means (DVS) of the preceding characters supplying the signals (VS) transmitted on the service channel;  fourth means for decoding (DI) information transmitted outside the service channel.  7. Transceiver constituting an intermediate station on a transmission path, for carrying out the method according to one of claims 1 to 4, characterized in that it comprises:  first reception means (RR, RVT) of the transmitted information;  second extraction means (E) of all the characters assigned to the service channel;  third means (DVS, CVS) decoding the preceding characters and possibly encoding new signals (VS ') to be transmitted on the service channel;  fourth means (L) carrying out, where appropriate, the insertion of the new coded signals to be transmitted on the service path, replacing the preceding characters; ;  fifth means (E) for transmitting the information provided by the fourth means.