FR2576169A1 - Device allowing connection and transmission of signals in both directions between two transmission lines containing a different number of conductor pairs - Google Patents

Abstract

A device for connecting between two lines containing a different number of conductor pairs, in particular one pair and two pairs of conductors respectively, according to the invention, includes one transformer per pair of conductors involved. Each of the secondary windings of the transformers, the primary windings of which are connected to the line containing two pairs of connectors, is connected to one of two windings of a three-winding transformer via a transistor. The two transistors are supplied alternately by a square- wave generator, one allowing through the signal whilst the other blocks it. The third winding of the said three-winding transformer is connected to the network with single conductor pair.

Description

"Device for connecting and transmitting signals in two directions between two transmission lines comprising a different number of pairs of conductors
teurs ".

 The present invention relates, in general, to connections between different communications networks, in particular telephone networks.

 The telephone link between two stations X and Y can be ensured by a circuit with four conductors, two of which are assigned to the transmission of the modulation from X to Y, the other two, to the reception, in X, of the modulation coming from Y. Another, older, but still commonly used mode of transmission uses only two conductors to perform the two functions. In this latter case, a balancing circuit makes it possible to avoid retransmission by each of the stations of the modulation received from the other, a precaution under which oscillations at audible frequency begin.

 The four-conductor solution allows exchanges at very different electrical levels, while compensation on the two-conductor circuit is only practicable for comparable levels.

 Most modern auxiliary equipment is made to be used on four-conductor networks because of the definite advantages of these.

However, there are many two-conductor circuits for which the use of new equipment, although desirable, is not possible in the current state of the art.

 The object of the device, object of the present invention, is to allow this adaptation of lines with two conductors, to equipment or networks with four conductors.

 The description of the claimed principle can be followed in the diagram in FIG. 1, while a practical embodiment of the invention is diagrammed in FIG. 2. A variant application of the same principle is briefly indicated in the diagram in FIG.

 To this end, the invention consists of a device making it possible to connect, for the transmission of so-called "modulation" electrical signals in both directions, a first line of the kind comprising two pairs of conductors with a second line comprising a single pair of conductors, characterized in that the so-called first windings of two transformers are connected to the two pairs of conductors of said first line, in that the so-called second windings of these transformers are each connected via a so-called main transistor , made alternately conductive and non-conductive by an alternating signal generator, respectively to a winding of a third transformer with three windings, the third winding of which is connected to the pair of conductors of the second line.

 Thus, it is possible by means of a sampling of the modulation signals, to pass these from one network to another by distributing the time allocated to the transmissions in one direction and in the other.

 Advantageously, said alternating signal generator produces signals in the form of slots of fundamental frequency substantially higher than the highest of the frequencies of the modulation signals which it is desired to transmit, and supplies, so as to make them alternately conductive, the two main transistors through which the transmitted signals pass.

 It is also preferable to charge the lines with constant impedances, which allows rapid alternation of the variation in conductivity of the transistors.

 Thus, the distribution of the time allocated to the transmission in one direction and the other, which amounts in fact to a division of this time in two for each modulation signal, does not affect the quality of this transmission to which is linked the intelligibility of the signal.

 According to another aspect of the invention, said alternating signal generator also supplies two so-called secondary transistors each connected respectively to the terminal of a winding of said third transformer opposite to the terminal of the same winding to which a main transistor is connected.

 Thus, parasitic components due to the switching transients produced by the generator and tending to be superimposed on the signal are eliminated, compensating for each other.

 According to another embodiment of the invention each of said secondary transistors is connected in phase opposition with the main transistor to which it corresponds, each connection being made upstream of one of the terminals of two of the windings of said third transformer.

 Thus, a compensation similar to that of the previous embodiment is obtained, parasitic components produced by the generator according to an assembly which may be easier to implement than that previously described.

The advantages and characteristics of the invention will also emerge from the description which follows by way of example with reference to the appended schematic drawings in which
FIG. 1 is a schematic diagram illustrating the general principle of 1-invention,
FIG. 2 is a schematic diagram illustrating an embodiment of the invention, and
FIG. 3 is a partial schematic diagram illustrating an alternative embodiment of an embodiment of the invention, the parts not shown being assumed to be identical to those which correspond to them in FIG. 2.

 - 1 is a low frequency line transformer, the primary 2 of which receives, by two conductors, id modulation voltage from the remote station X equipped with four conductors.

 The secondary 3 of this transformer shunted by the resistor 4, with a value close to 600 ohms, transmits, through the capacitor 5, this modulation at the base 6 of the transistor 7. The resistors 8 and 9 constitute the basic bridge of 7, while the resistor 10, slightly less than 600 ohms constitutes the load, in direct current, of its collector.

 The alternating component, amplified or only transmitted by 7, attacks, through the capacitor 11, the primary 12 of the transformer 13 whose winding 14 is connected to the line two conductors going-to the remote station Y.

 The winding 15 of the transformer 13 transmits the voltages of which it is the seat, induced by 12, towards the base 17 of the transistor 18. The resistors 19 and 20 constitute the basic bridge of 18, of which the resistance 21, slightly less than 600 ohms, is the load, in direct current of its collector.

 The modulation component, amplified or simply transmitted by 18, is applied, through the capacitor 22, to the primary 23 of the line transformer 24. The secondary 25 of the latter is connected to the two conductors carrying the modulation from Y to the remote station X.

 The resistors 9 and 20 of the basic bridges of 7 and 18 are connected respectively to points 27 and 28 of an oscillator called flip-flop generator of slots 26, the two outputs 27 and 28 being, at each tilting of the flip-flop to opposite states, that is to say when 27 is high or positive, 28 is zero, and vice versa.

More specifically, the operation of the principle circuit described above is as follows
When point 27 of the slot generator is in the positive state with respect to ground, while point 28 is itself in the zero state at ground potential, transistor 7 is conductive and the modulation arriving from
X on transformer 1, spring, amplified or not, on the line two conductors, at the terminals of 14. In this state of the flip-flop, the base 17 of transistor 18 being at zero, the latter is blocked and the voltage induced in 15 cannot be transmitted to the line connected to the terminals of 25.

 On the next tilting of the flip-flop, it is on the contrary 7 which is blocked and 18 which is on; the modulation voltages coming from the remote station Y can be transmitted to X by the pair of conductors connected to the secondary 25 of the transformer 24.

 If the switching frequency of 26 is appreciably higher than the limit frequency of transmission on the telephone lines concerned, Y will receive a sufficient sampling of the modulation coming from X which, likewise, will receive a sampling of what is emitted by Y.

 By this alternation arrangement, there will at no time be a mixture of the two modulations, the respective levels of which may therefore be very different.

 We note, on the diagram, that the lines are permanently looped on resistances equal to their characteristic impedance. Indeed, the secondary 3 of the transformer 1 is shunted by the resistor 4; the value of the impedance carried over to the terminals of 14 is defined by the value of 10, whether the transistor 7 is blocked or on. Similarly, the impedance carried over to the terminals of 25 is fixed by the value of the resistor 21.

For the three resistors 4, 10 and 21, the exact value of the impedance must take into account the direct and reported resistances of the windings which are associated with it. The rapid succession of functions is thus made possible by the constancy of the line load impedance.

 The operation set out above "as the basis of the invention presents in its implementation a significant difficulty. In fact, the rapid succession of Rblocked" / "conductor" states of the transistors, by varying - at the same rate the currents of supply to the collectors, and therefore the potential of these, induces significant parasitic voltages in the windings.

Figure 2 shows a circuit according to the invention in which means are provided capable of eliminating said drawback. We find there the elements of the first diagram, with the same location of the elements, assigned to the same functions.

 To avoid the appearance of a transient current in the primaries of the transformers, which would result from the periodic variation of the potential of the collectors of the transistors 7 and 18, the potential at the other end of the windings is varied simultaneously and with the same amplitude. correspondents.

 By way of example, to consider the mechanism of this compensation, consider the circuit associated with transistor 7. Instead of being closed to ground, the winding 12 is connected to the collector of an additional transistor 29, having resistor 30 for continuous charge. The base 31 of the transistor 29 has, for the determination of its potential, the resistor bridge 32 and 33. This resistor 33 is supplied exactly in phase with the resistor 9 of the base bridge of the transistor 7; in this way, the blocking and conduction cycles of 7 and 29 are synchronous. The potentiometers 34 and 35, connected in parallel and supplied between ground and point 27 of the flip-flop 26 make it possible to adjust the operating points of the two transistors. Only the base of 7 receives the low frequency component to be transmitted. To limit as much as possible the attenuation introduced by the presence of the resistor 30 in series in the winding 12, this is given a low value, and we chooses transistor 29 capable of accepting a collector current much higher than that of 7, set for transmission to the minimum of distortion. Under these conditions, to satisfy the desired condition of equal potentials on the two collectors of 7 and 29 it is necessary that at all times the products RIO x i7 and R30 x i29 are equal, i7 and i29 being the corresponding collector currents .

 To ensure this condition in practice, the high potential delivered by the latter is temporarily assigned to the output terminal 27 of the flip-flop; we set the cursor to 35 to cause the transistor 7 to transmit with zero or very little distortion the alternating signals applied to its base 6 through the capacitor 5. We then measure the DC potential on the collector of 7. Just adjust the cursor of 34 to bring the collector of 29 to the same potential. Under these conditions, the entire winding 12 will, upon re-establishing the functioning of the flip-flop, be subjected to variations in the breaking potential of said flip-flop, without the appearance of current, therefore of parasitic voltage induced in the transformer, other than that due to the capacity between windings, which an appropriate construction of the transformer 13 makes it possible to eliminate.

 The above description, taken as an example, concerns the circuit associated with transistor 7, compensated by 29. It is exactly transposable to the circuit of transistor 18, compensated by 36, both being controlled synchronously by point 28 of the flip -flop 26.

 The compensation mode described above and illustrated by the diagram in FIG. 2 therefore makes it possible to establish at all times the equality of variable potentials on the collectors of two transistors in the alternating transmission by sampling the alternative components.

 Another possible solution to avoid the production of disturbing voltages in the lines consists in keeping constant the average potential of the collector ensuring the transmission, rather than compensating for the cyclic variations of this potential. The diagram in Figure 3 very briefly represents an embodiment providing a such a solution, this diagram representing only one of the two signal transmission channels, it being understood that the second channel is produced in the same way.

 In the diagram in FIG. 3, the transistor 52, responsible for transmitting the signals and the transistor 43 has the role of compensating at all times the variations in the mean collector current of 52 due to the switching. These two transistors have a common collector load resistor 53. The resistor 45 of the base bridge of 52 being connected to the output 48 of the flip-flop 50, and the resistor 47 of the base bridge of 43 being connected to the output opposite 49 of the flip-flop, transistor 52 will be conductive while 43 will be blocked and vice versa. An appropriate setting of the currents in the two transistors makes it possible to keep the sum of these switching currents in 53 constant, which is precisely what it is desired to obtain.

 However, a possible drawback of such an arrangement is the appearance of very brief variations in the average current during the flip-flop tilting time, a drawback whose effects are mitigated by the addition of a capacity 51, of sufficient value. to tend to maintain during the switching time the average value of the voltage at the terminals of the common load 53, without however attenuating the sampling of the useful modulation.

 In the descriptions and the description of the operation given above, it is described, by way of example, only the application to telephone lines whose characteristic impedance is 600 ohms. It is obvious that the device according to the invention is also applicable for lines of different characteristics. In particular, a very important advantage of the system is to allow a connection between lines four conductors and two conductors of different impedances, or even between cable connections and overhead lines and this, while retaining the possibility of working with very different levels between the two directions of transmission. Likewise, it is possible to establish connections between lines comprising several pairs of conductors by extension of the device described and illustrated.

 It should be understood that the term telephone modulation is absolutely not limiting, the device according to the invention being just as well suited to any transmission of coded information, remote control signals or telegraph telemetry at two frequencies called "shift" ", data transmission and more generally to the transposition between two link systems, of all the information likely to be transmitted by telephone lines.

Claims (6)

 1. Device making it possible to connect, for the transmission of so-called "modulation" electrical signals in both directions, a first type line comprising two pairs of conductors with a second line comprising a single pair of conductors, characterized in that the so-called first windings of two transformers are connected to the two pairs of conductors of said first line, in that the so-called second windings of these transformers are each connected by means of a so-called main transistor, made alternately conductive and non-conductive by an alternating signal generator, respectively to a winding of a third transformer with three windings, the third winding of which is connected to the pair of conductors of the second line.  2. Device according to claim 1 characterized in that said alternating signal generator produces signals in the form of slots of fundamental frequency substantially higher than the highest of the frequencies of the modulation signals which it is desired to transmit.  3. Device according to any one of claims 1, 2 characterized in that said alternating signal generator supplies so as to make the two main transistors alternately conductive through which the transmitted signals pass.  4) Device according to any one of the preceding claims, characterized in that the lines of the device are loaded by constant impedances.  5. Device according to any one of the preceding claims, characterized in that said alternating signal generator also supplies two so-called secondary transistors each connected respectively to the terminal of a winding of said third transformer opposite to the terminal of the same winding to which is connected a main transistor.  6. Device according to any one of claims 1 to 4 characterized in that each of said secondary transistors is connected in phase oppQsition with the main transistor to which it corresponds, each connection being made upstream of one of the terminals of two of windings of said third transformer.