CH640678A5 - METHOD AND INSTALLATION FOR THE SIMULTANEOUS TRANSMISSION OF A LOW FREQUENCY WAVE AND A MIC DIGITAL SIGNAL. - Google Patents

Description

The present invention relates to a method allowing the simultaneous transmission of additional information, in the form of a low frequency wave modulated or not, with an incoming digital signal MIC and an installation implementing this method. It relates more particularly to digital data or information transmission systems which convey a digital signal whose digits can have two levels (1.0), like a bit, or three levels (-1,0,1), like a ternary digit. In what follows we will designate by high level or level “H” the states “1”, whether they are positive or negative.

It is often difficult in such digital transmission systems to transmit additional information, on the one hand, without increasing the complexity of the equipment.

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transmission and reception and, on the other hand, without using an additional transmission medium, such as an auxiliary pair of a coaxial cable.

The present invention aims to allow the transmission of additional information without using an additional transmission medium, in the case where there is already developed transmission equipment, associated with one or more reception equipment constituted by very simple circuits.

To this end, the method according to the invention is characterized in that the parity of the high levels of the digital signal entering by the low frequency wave is modulated. The low frequency wave can constitute the additional information in itself or be modulated by the additional information. To transmit the low frequency wave, the transmission method according to the invention calls for checking the parity of the "H" levels. A method for checking the parity of the “H” levels in repeaters is already known for detecting the rate of errors in service. This method is described in contributions n ° 59 and 54 of study groups XVIII and IV of the International Telegraph and Telephone Consultative Committee. According to this known method, in the absence of error, the parity of the levels “H” between specified times must be even, that is to say that the number of levels “H” between these specified times is even.

According to the present invention, the transmission method uses not, not a constancy of the parity but an alternation of the parity of the "H" levels. Indeed, the transmission method according to the invention is remarkable in that the parity of the "H" levels is modulated at the rate of a low frequency wave which can itself be modulated by the additional information to be transmitted.

Depending on the case, the modulation of the parity of the “H” levels can be carried out according to different modes.

When the digital signal is a binary signal, a first mode of modulating the parity of the “H” levels consists in appreciably increasing the bit rate of the digital signal to be transmitted, so as to be able to periodically insert words at the rate of the low frequency wave. additional binaries. Each additional binary word is formed by one or more binary digits which depend on the phase or the logic level of the low frequency wave so that the parity of the resulting digital signal is constantly even, respectively odd during the intervals where the phase or the logic level of the low frequency wave is constant.

In the case of a ternary digital signal, this first modulation mode is still applicable, the “H” levels being counted, whether positive or negative.

In the case of a binary digital signal made random by a jammer or "scrambler", it is useless to insert additional digits. In this case, a second mode of modulating the parity of the “H” levels consists in coding the digital signal leaving the jammer according to a code having redundancy; thus, to a word having there binary digits corresponds at least two words of m ternary digits. At least one of these ternary words changes the parity of the “H” levels of the signal and at least one other does not change it.

It is not necessary that the state of the parity of the levels “H” be determining for the choice of the word of m ternary digits for all the configurations of words to n. binary digits. In a preferred embodiment of the present invention, produced from an n B m T coding, for example of the type known under the name MS 43, it is only for coding the 1100 configuration of four digits binary that account is taken of the parity of the "H" levels. The well-known code MS 43 corresponds to each configuration of four binary digits, three different alphabets A ,, A2, A3 according to table I below:

Table I

s Binary a]

a2

a3

0000

+ -0

+ -0

+ -0

0001

+ +0

00-

00-

0010

+ 0 +

0-0

0-0

1O0011

0+ +

- - +

- +

0100

+ + -

+ -

+ -

0101

0- +

0- +

0- +

0110

-0 +

-0 +

-0 +

0111

+ - +

+ - +

151000

+ + +

- + -

- + -

1001

+ 0-

+ 0-

+ 0-

1010

0+ -

0 + -

0H—

1011

- + +

- + +

0

1100

+ 00

+ 00

- 00

201101

0 + 0

0 + 0

-0-

1110

00 +

00 +

0

1111

- + 0

- +0

BO

Usually the choice of the alphabets Ab A2 and A3 is determined by the algebraic value of the sum of the levels 1 and - 1 determined at the end of each ternary word. This sum, called synchronized sum, is deliberately limited to the values - 2, -1.0 and 1; to do this, the alphabet Aj is used for each ternary word when the synchro-3C sum nized at the end of the previous ternary word is - 2, the alphabet A2 is used when this same sum is equal to - 1 or 0 and the alphabet A3 is used when the synchronized sum is equal to +1, this according to the usual and known use of the three-level code MS 43.

35 By way of example, the adaptation of the code MS 43 consists in keeping all of table I and the above rules except for the thirteenth line of table I which corresponds to the binary word 1100. This line is replaced by the two lines of table II below:

Table II

binary

1100

Ai 000

a2

000

+ 00 +00

a3,000

-00

50

The first of the last two lines of Table II is used if we want to keep the existing parity of levels "H", and the second line is used if we want to change the existing parity of levels "H". Furthermore, the choice of the alphabets A !, A2 and A3 is always made according to the value of the synchronized sum.

A transmission device implementing the first mode of modulation of the levels "H" comprises a time base for producing a rhythm signal at a higher rate than that of the incoming digital signal, a circuit for detecting the parity of the levels " H "of the incoming digital signal and a circuit controlled by the time base and the detection circuit for inserting additional digit words so that in the resulting digital signal leaving the parity of the levels" H "depends on the phase or of the logic level of the low frequency wave and is constantly even, respectively odd during the intervals where the phase or the logic level of the low frequency wave is constant.

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The circuit for inserting the additional words comprises a buffer memory receiving the incoming digital signal, a counter connected to the time base for controlling the writing of the buffer memory at the frequency of the incoming digital signal, a counter connected to the time base. time to control the reading of the buffer memory at the frequency of the resulting digital signal leaving, an AND gate having a first input receiving the low frequency wave and a second input connected to the circuit for detecting the parity of the "H" levels, a OR gate having a first input connected to the output of the AND gate and a second input connected to the output of the buffer memory and a shaping circuit controlled by the time base and having its input connected to the output of the gate OR and its output delivering an outgoing resulting digital signal.

A transmission device implementing the second mode of modulation of the “H” levels comprises a jammer of the incoming binary digital signal, a transcoder for selectively converting each word with n binary digits of the scrambled signal into a word with m ternary digits modifying or not the parity of the levels "H" of the outgoing digital signal, a circuit connected to the output of the transcoder to detect the parity of the levels "H" of the outgoing digital signal and a circuit receiving the low frequency wave and connected to the output of the circuit of detection to compare the parity of the “H” levels of the outgoing digital signal and a parity fixed by the phase of the low frequency wave in order to control the selection of the words with m ternary digits in said transcoder.

The reception device for receiving the low frequency wave and consequently the additional information transmitted according to the method of the invention is essentially composed of a flip-flop and a bandpass filter whose central frequency of the band bandwidth is equal to the frequency of the transmitted LF wave or to a multiple of this frequency.

However when the transmission of the digital signal is marred by errors a better reception of the additional information transmitted is obtained by inserting between the flip-flop and the bandpass filter a low-pass filter and a rectifier circuit with single or double alternation.

The main advantage of the method according to the present invention lies in the simplicity of the installation necessary for its implementation, particularly remarkable simplicity with regard to the devices necessary for the reception of the low frequency wave transmitted simultaneously with the digital signal.

Other features and advantages of the present invention will appear during the following description of several exemplary embodiments, with reference to the corresponding drawings in which:

- Fig. 1 is a schematic block diagram of the transmission device implementing the first mode of modulation of the parity of the levels "H", by means of which it is possible to transmit according to the invention additional information:

- Fig. 2 is a detailed block diagram of the circuit for inserting the additional bits of the transmission device of FIG. 1;

- Fig. 3 is a schematic block diagram of the transmission device implementing the second mode of modulating the parity of the levels "H", by means of which it is possible according to the invention to transmit additional information;

- Fig. 4 is a schematic block diagram of the reception device making it possible to restore the additional information;

- Fig. 5 is a schematic block diagram of another embodiment of the reception device used mainly when the transmission of the digital signal is marred by errors; and

- Fig. 6 shows, by way of example, the shapes of some of the control pulse trains supplied by s the time base of the transmission device.

Referring to FIG. 1, the digital signal, or high frequency signal (HF) to be transmitted in the form of a train of binary or ternary digits, feeds the input terminal 1 of the transmission device 2 allowing the transmission according to the io vention of additional information. This additional low frequency information feeds the input terminal 3 of this same device. The input terminal 1 is connected to the input terminal 4 of a time base 5, to the input terminal 6 of an additional bit insertion circuit 7 and to the input terminal 15 a circuit for detecting the parity of the “H” levels 9. This circuit 9 is for example a flip-flop which changes state under the influence of each rising edge of the digital signal to be transmitted. In the case of a ternary digital signal, the flip-flop 9 is preceded by a rectifier 10 il-20 with dotted lines in FIG. 1. The output terminal 11 of the parity detection circuit 9 is connected to a first control terminal 12 of the circuit for inserting additional bits 7. An output terminal 13 of the time base 5 produces the rhythm frequency of the incoming digital signal to be transmitted, as shown in line a of FIG. 6, and is connected to a second control terminal 14 of the circuit 7. A second output terminal 15 of the time base 5 produces a signal at the rhythm frequency at which the outgoing signal will be transmitted including the digital signal and the additional information, as shown in line b of FIG. 6, and is connected to a third control terminal 16 of the circuit 7. The time base 5 also supplies an output terminal 17 with a low frequency carrier wave, as shown in line c of FIG. 6. The output terminal 17 is connected to the input terminal 18 of a modulator circuit 19, a first input terminal 20 of which is connected to the second input terminal 3 of the transmission device 2. The terminal output 21 of the modulator circuit 19 delivers the carrier wave BF modulated by the additional information to be transmitted, and is connected to a fourth control terminal 22 40 of the circuit 7. Another output terminal 23 of the time base 5 is connected to a fifth control terminal 24 of the circuit for inserting additional bits 7. This output terminal 23 supplies a rhythm signal which is at the same frequency as that shown on line b of FIG. 6, but has 45 holes as shown in line d of FIG. 6. In other words, the rate of the rhythm signal shown at line d in Fig. 6 during a period of the low frequency wave is substantially greater than the rate of the rhythm signal shown in line a of FIG. 6.

The output terminal 25 of circuit 7 is connected to the output terminal 26 of the transmitting device 2 and transmits the resulting digital signal leaving with a higher rate than that of the incoming digital signal at terminal 1.

In Fig. 2 is shown in more detail the circuit for inserting 55 additional bits 7 with its input terminal 6, its output terminal 25 and its control terminals 12, 14, 16, 22 and 24. The terminal input 6 is connected to a buffer memory 30, the writing of which is controlled by a so-called writing counter 31 connected to the input terminal 14 and the reading of which is controlled by a counter known as the reading 32 connected to the input terminal 24. The control terminals 12 and 22 are connected to the input terminals of an AND gate 33, the output terminal 34 of which is connected to a first input terminal 35 of an OR gate 36. The se-6s conde input terminal 37 of the OR gate 36 is connected to terminal 38 of the buffer memory 30. The output terminal 39 of the OR gate 36 is connected to the input terminal 40 of a circuit shaping 41 which is controlled by the rhythm signal supplied to the control terminal 16 and whose output terminal is the

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output terminal 25 of the additional bits insertion circuit 7.

As an example, an additional three-bit word is inserted every 200 binary digits. This additional word will have one or the other of the two following configurations: 001 and 110. The first configuration is used when the state of the parity of the levels "H" is to change. The second configuration is used when the existing parity state of the “H” levels is to be kept.

Fig. 3 schematically represents a second embodiment of the transmission device for modulating the “H” levels of an incoming binary digital signal. This device 50 has two input terminals 51 and 52 and an output terminal 53. The incoming binary signal to be transmitted is received by the input terminal 51 which is the input terminal of an interfering circuit 54 (in English "Scrambler"). The output terminal 55 of the interfering circuit 54 supplies the binary signal made random at the input terminal 56 of a transcoder 57. The transcoder 57 converts each word of 11 binary digits into a word of m ternary digits. The output terminal 58 of the transcoder 57 is connected to the output terminal 53 of the transmitting device 50 and to the input terminal 59 of a circuit for detecting the parity of the "H" levels 60. The output terminal 61 of circuit 60 is connected to the first input terminal 62 of a comparison circuit 63 to compare the existing parity and the desired parity which is fixed by the phase of the low frequency carrier wave which is or is not modulated. The input terminal 52 of the transmission device 50 receives the low frequency carrier wave and is connected to a second input terminal of the comparison circuit 63. The output terminal 64 of the comparison circuit 63 is connected to the terminal 65 of the transcoder 57 and selectively controls the transcoder 57 so that a choice of words with m ternary digits which modify or not the parity of the “H” levels of the outgoing signal, corresponds to at least one word with il binary digits of the scrambled signal. This choice is made in dependence on the parity of the outgoing signal and the prity fixed by the phase of the low frequency carrier wave. The change from the binary code to a ternary code in the transcoder 57 and the selection of the alphabets A ,, A2 and A3 when the MS code 43 is used, are accomplished, as already said, according to Tables I and II.

Fig. 4 shows clearly all the simplicity of the reception device 70 necessary for the reception of the low frequency wave and as a result of the additional information transmitted according to the invention. The input terminal 71 of the reception device 70 receives the resulting digital signal leaving by the output of the transmission device, via the transmission line. The input terminal 71 is the input terminal of a flip-flop 72 whose output terminal 73 is connected to the input terminal 74 s of a band-pass filter 75 reproducing the low frequency wave. The output terminal 76 of the bandpass filter 75 is the output terminal of the reception device 70. The passband of the filter 75 is centered on a frequency equal to the frequency of the low frequency wave conveying additional information. be silent or at a frequency multiple of the latter.

Fig. 5 shows a variant of the device for receiving the additional information. The use of this variant is more particularly indicated when the online transmission of the digital signal is marred by errors. The reception device 80 according to this variant also comprises a flip-flop 72 whose input terminal 71 receives the resulting digital signal leaving the transmission device and is the input terminal of the reception device 80. input 82 of a low-pass filter 81 is connected to the output terminal 73 of the flip-flop 72. The input terminal 84 of a rectifier circuit 83, single or double alternation, is connected to the terminal of output 85 of the low-pass filter 81. A band-pass filter 86 has its input terminal 87 connected to the output terminal 88 of the rectifier circuit 83 and to its output terminal 89 merged with the output terminal of the reception 80. The low frequency wave transmitting the additional information is delivered by the output terminal 80.

Advantageously, the cut-off frequency of the low-pass filter 81 is significantly higher than the frequency of the low-frequency wave 30, and the frequency of the pass band of the band-pass filter 86 is equal to twice the frequency of the wave. low frequency.

The method and the installation according to the invention are advantageously used each time it is desired to transmit si-35 simultaneously and on the same support a digital signal and a low frequency wave of additional information. The transmission of the resulting digital wave can then constitute information in itself; for example, measuring its voltage level at any point on the trans-40 mission provides information on the quality of the digital signal transmission. Jointly or not, the low frequency wave can be modulated to transmit specific information between two main stations or a main station and a chain of intermediate repeaters.

VS

2 sheets of drawings

Claims (11)

-00 in which the first line of words with three ternary digits is used when the parity of the high levels of the resulting outgoing signal is to be kept and the second line of words with three ternary digits is used when the parity of the high levels of the resulting signal outgoing is to be changed, the choice of said three alphabets for each ternary word in said transcoder (57) 30 depending on the value of the synchronized sum of the preceding ternary word in the resulting outgoing signal. + 00 +00,000 1,100,000,000 640,678 1. Method for the simultaneous transmission of additional information, in the form of a low frequency wave modulated or not, with an incoming digital signal MIC, characterized in that one modulates the parity of the high levels of the incoming digital signal by l 'low frequency wave. 2. Method according to claim 1, characterized in that the bit rate of the digital signal to be transmitted is increased and in that periodically additional words of digits are inserted which depend on the phase or the logic level of the low wave frequency so that the parity of the high levels of the resulting digital signal is constantly even, respectively odd during the intervals where the phase or the logic level of the low frequency wave is constant. 2 3. Method according to claim 1, in which the incoming binary digital signal to be transmitted is made random and coded into a resulting ternary digital signal outgoing according to a code having redundancy, characterized in that at least one word of binary ij_digits corresponds a choice of words of m ternary digits modifying or not the parity of the high levels of the resulting resulting digital signal and in that the choice is made according to the existing parity of the high levels and the desired parity fixed by the phase of the low frequency wave to transmit. 4. Installation for implementing the method according to claim 1, characterized in that it comprises a transmitting device (2; 50) receiving the low frequency wave modulated or not and the incoming digital signal to modulate the parity high levels of the incoming digital signal by the low frequency wave into an outgoing resulting digital signal, and a receiving device (70; 80) receiving said resulting digital signal emitted by the transmitting device (2; 50) to output the wave at low frequency. 5. Installation according to claim 4, for the implementation of the method according to claim 2, characterized in that the transmission device (2) comprises a time base (5) for producing a rhythm signal at a higher rate higher than that of the incoming digital signal (1), a circuit (9) for detecting the parity of the high levels of the incoming digital signal and a circuit (7) controlled by the time base and the detection circuit (9) for inserting additional digit words so that in the resulting outgoing digital signal (26) the parity of the high levels depends on the phase or the logic level of the low frequency wave and is constantly even, respectively odd during the intervals where the phase or the level logic of the low frequency wave is constant. 6. Installation according to claim 5, characterized in that the circuit for inserting additional words (7) comprises a buffer memory (30) receiving the incoming digital signal (1.6), a counter (31) connected to the base time (5) for controlling the writing of the buffer memory (30) at the frequency of the incoming digital signal, a counter (32) connected to the time base (5) for controlling the reading of the buffer memory (30) at the frequency of the resulting outgoing digital signal (25,26), an AND gate (33) having a first input (22) receiving the low frequency wave and a second input (12) connected to the level parity detection circuit high (9), an OR gate (36) having a first input (35) connected to the output (34) of the AND gate (33) and a second input (37) connected to the output (38) of the buffer memory (30) and a shaping circuit (41) controlled by the time base (5) and having its input (40) connected to the output (39) of the OR gate (36) and its output (25) del dropping the resulting outgoing digital signal (26). 7. Installation according to claim 4, for the implementation of the method according to claim 3, characterized in that the transmission device (50) comprises a jammer (54) of the incoming binary digital signal (51), a transcoder ( 57) to selectively convert each word with 31 binary digits of the scrambled signal into a ternary mdigit word modifying or not the parity of the high levels of the outgoing digital signal (53), a circuit (60) connected to the output (58) of the transcoder (57) for detecting the parity of the high levels of the outgoing digital signal (58), and a circuit (63) receiving the low frequency wave (52) and connected to the output (61) of the detection circuit (60) for comparing the parity of the high levels of the outgoing digital signal and a parity fixed by the phase of the low frequency wave in order to control the selection of the words with m ternary digits in said transcoder (57). 8. Installation according to claim 7, characterized in that the code used in the transcoder (57) is the three-level code MS43 having three alphabets A ,, A2 and A3 which are modified only for the 4-bit word 1100 of the incoming signal according to the following table: Binary ai a2 a3 20 9. Installation according to one of claims 4 to 8, characterized in that the reception device (70) comprises a flip-flop (72) receiving the resulting digital signal 35 emitted by the transmission device, and a pass filter band (75) connected to the output of said flip-flop (72) and having a frequency band centered on a frequency which is equal to the frequency of the low frequency wave or to a multiple of this frequency. 40 10. Installation according to one of claims 4 to 8, characterized in that the reception device (80) comprises a flip-flop (72) receiving the resulting digital signal emitted by the transmission device, a low-pass filter ( 81) connected to the output (72) of the scale (72), a rectifier circuit (83) connected 45 to the output (85) of the low-pass filter (81) and a band-pass filter (86) connected to the output (88) of the rectifier circuit (83). 11. Installation according to claim 10, characterized in that the pass band of the band pass filter (86) is centered on the frequency twice the frequency of the low frequency wave.