FR2601836A1 - Multiconversation device - Google Patents

Abstract

The multiconversation device comprises n gateway circuits A1 to An connected to an exchange, and n multiplexing circuits M1 to Mn. Each gateway circuit is associated with a multiplexing circuit to which it is connected by an incoming line LE1 to LEn; each gateway circuit is connected by an outgoing line LS1 to LSn to all the multiplexing circuits, except that with which it is associated. A reception path of the gateway circuit comprises an input transformer, a circuit with low threshold, a phase-analyser circuit, an adder/suppressor circuit and a broadcasting circuit; a transmission path includes an adapting circuit, an expander/compressor circuit and an output transformer. The input and output transformers and connected to the exchange by two-wire lines E1 to En; S1 to Sn.

Description

Multiconversation device
The invention relates to a multiconversation device allowing the interconnection of transmission lines and more particularly of telephone lines.

 The invention finds applications in "telephone meeting" and "teleconviviality". The "telephone meeting" allows the simultaneous conversation of several participants, the number of which is generally limited to around twenty; it requires a prior request to the Administration which provides a telephone number, a time slot, the applicant having indicated the number of participants.

 Teleconviviality allows a number of participants of the order of fifteen people to converse from a known telephone number, published for example in the press; unlike the "meeting telephone" access is completely free and there is no time slot imposed.

 The existing multiconversation devices encountering an important problem which is that of the creation in the access network (switched telephone network) of an echo signal. An echo signal is difficult to control, since it originates at a point on the network outside the multiconversation device; moreover the level of an echo signal, as well as its propagation time are random finally each participant giving birth in the network to an echo signal, the sum of the echo signals generated by each participant gives a signal d 'global echo whose level, variable is all the more important as the number of participants is high, so that any conversation becomes difficult if not impossible when the level of the global echo signal is too high because it occurs phenomena d priming due to the sum of the echoes.

 Another problem is that of the significant difference in level between the signals coming from the participants and applied to the multiconversation device, so that on transmission the signals transmitted reproduce these differences in level; this has the consequence that a participant will receive signals whose levels are very different, depending on whether they correspond to such or such participant, hence a very great difficulty in listening, the ear taking some time to s '' adapt to these level changes.

 The invention therefore aims to remedy the shortcomings of existing multiconversation devices.

 The subject of the invention is a multiconversion device comprising n access circuits connected to an office, each access circuit comprising a reception channel having an input connected to the office and an output, a transmission channel having an input and an output connected to the central, characterized in that it comprises n multiplexing circuits, each multiplexing circuit being associated with an access circuit and having nl inputs and one output, that each access circuit has the input of its connected transmission channel by an incoming line at the output of the multiplexing circuit with which it is associated, and the output of its reception channel connected by an outgoing line to an input of each multiplexing circuit, except the one with which it is associated, and that a distributor is connected by a bus to the multiplexing circuits, said distributor delivering cyclically nl addresses.

 The invention will be better understood from the following description of embodiments illustrated by the appended figures in which, - FIG. 1 schematically represents a multiconversation device of the invention, - FIG. 2 represents an access circuit of the device of Figure 1, - Figure 3 shows a multiplexing circuit of the device of Figure 1.

 FIG. 1 schematically represents a multiconversation device of the invention, comprising n access circuits A1 to An, n multiplexing circuits M1 to Mn and a distributor 1.

 The access circuits are connected to an office (telecommunication central) by a two-wire input El to En and a two-wire output S1 to Sn, respectively, each access circuit being connected by the central and the network to a participant. An access circuit is connected to a multiplexing circuit by an incoming line; the access circuit Al is connected to the multiplexing circuit M1 by the incoming line LE1, the access circuit A2 is connected to the multiplexing circuit M2 by the incoming line LE2,, the access circuit An is connected to the multiplexing Mn by the incoming line LEn.

 Each access circuit is connected by an outgoing line LSi to all the multiplexing circuits except that to which it is connected by an incoming line; thus the access circuit A1 is connected by the outgoing line LS1 to the multiplexing circuits M2 to Mn, the access circuit A2 is connected by the outgoing line LS2 to the multiplexing circuits M1 and M3 to Mn, the access circuit An is connected by the outgoing line LSn to the multiplexing circuits M1 to Mn-1; each multiplexing circuit therefore has n-l inputs.

The distributor 1 comprises a time base BT which delivers a clock signal to a counter 2 with four outputs, A, B, C, D; a bus BC connects the outputs of the counter to all the multiplexing circuits M1 to
Mn. The counter cyclically delivers nl addresses to the multiplexing circuits.

 FIG. 2 represents an access circuit Ai of the multiconversation device of FIG. 1. It comprises a transmission channel and a reception channel. The reception channel consists of an input transformer TF1, a low threshold circuit 10, a phase analyzer circuit 11, a summing / suppressor circuit 12 and a diffusion circuit 13. The transmission channel consists of an adapter circuit level 14, an attenuator 16, an expander / compressor circuit 15 and an output transformer TF2.

 The input transformer TF1 has a first winding el connected by its terminals AR and BR to the office and a second winding e2 having a first end connected to ground.

 The low threshold circuit 10 has a resistor 21 connected on the one hand to ground and on the other hand to the second end of the second winding e2, another resistor 22 connected on the one hand to the second winding e2 and on the other hand leaves at a point common to a resistor 23 and to a capacitor C1, the resistor 23 and the capacitor C1 being connected to ground; this common point constitutes the output of the low threshold circuit 10. Two diodes D1 and D2 are connected in parallel on the resistor 22, in opposite directions to one another.

 The phase analyzer circuit 11 comprises a first 37 and a second 38 operational amplifiers, each having a positive input connected to the point common to the resistor 23 and to the capacitor C1 of the low threshold circuit 10. A resistor 28 is connected between the input negative and the output of the first amplifier 37; a resistor 29 is connected the negative input and the output of the second amplifier 38.

 The negative input of the first amplifier 37 is connected by a resistor 24, on the one hand to ground through a resistor 26 and through a capacitor C2 and on the other hand to a cursor of a potentiometer P2 through a diode D3. The negative input of the second amplifier 38 is connected by a resistor 25 on the one hand to ground through a resistor 27 and through a capacitor C3 and on the other hand to the cursor of the potentiometer P2 through a diode D4; a capacitor C4 is mounted in parallel on the potentiometer P2.

 Anode of diode D3 and the cathode of diode D4 are connected to the cursor of potentiometer P2, one terminal of which is connected to ground and another terminal is connected by a resistor 20 to the output of the level 14 adapter circuit. The potentiometer constitutes an adjustable voltage divider.

 The outputs of the two amplifiers 37 and 38 constitute two outputs of the phase analyzer circuit 11.

 The summing / suppressor circuit 12 comprises two transistors T1 and T2. The transistor T1, of PNP type, has its emitter connected to the output of the first amplifier 37, and its base connected on the one hand to the cathode of a diode D5 whose anode is connected to ground, and on the other leaves at a positive potential + V by a resistor 30. The transistor T2, of NPN type, has its emitter connected to the output of the second amplifier 38, and its base connected on the one hand to the anode of a diode D6 of which the cathode is connected to ground, and on the other hand to a negative potential -V by a resistor 31. The collector of the transistor T1 is connected by a resistor 32 to a point F; the collector of transistor T2 is connected by a resistor 33 at point F. A resistor 34 is connected between point F and ground; the point F is also connected to earth by a resistor 35 in series with a potentiometer P1 whose cursor, connected to the diffusion circuit 13 constitutes the output of the summing / supressor circuit 12. The potentiometer P1 constitutes an adjustable voltage divider.

 The diffusion circuit 13 comprises an operational amplifier 39 having a negative input connected to its output, and a positive input connected through two resistors 51, 52 on the one hand to the cursor of the potentiometer P1, and on the other hand, to the ground by a series circuit constituted by a resistor 36 and two diodes D7 and D8 mounted head to tail and forming a clipper. A point common to the two resistors 51, 52 is connected by a wire 53 to the attenuator 16. The output of the amplifier 39 is connected to the outgoing line LSi which connects the access circuit Ai to the multiplexing circuits at the exception of the multiplexing circuit Mi as indicated during the description of FIG. 1.

 The level adapter circuit 14 is connected to the multiplexing circuit Mi by the incoming line LEi. It comprises a potentiometer P3 connected on the one hand to the incoming line LEi and on the other hand to ground, and an operational amplifier 48 having a negative input connected by a resistor 41 to the cursor of the potentiometer P3, said cursor being connected to the ground by a resistor 40. A resistor 42 connects the output and the negative input of the amplifier 48, the positive input of which is connected to ground. The output of amplifier 48 constitutes the output of level 14 adapter circuit.

 The expander / compressor circuit 15 comprises an operational amplifier 49 having a negative input connected by a resistor 43 on the one hand to the output of the level adapter circuit 14 and on the other hand to two diodes D9, D10 mounted head to tail, said diodes being connected by a resistor 44 to the positive input of amplifier 49, said positive input also being connected to ground by a resistor 45.

A resistor 46 connects the negative input and the output of the amplifier 49.

 The output transformer TF2 has a first winding e4 connected on the one hand to ground and on the other hand to the output of the amplifier 49 by a resistor 47, and a second winding e3 whose terminals AE and BE are connected to the office.

 The attenuator 16 is connected by a wire 54 to the output of the adapter circuit 14, and is shown in FIG. 4.

 The wire 54 is connected by a switch 76 to the input of an operational amplifier 75; a diode bridge 71, 72, 73, 74 has a first branch having a terminal connected to the output of the amplifier 75 and another terminal connected to ground, and a second branch having a positive terminal connected by a resistor 67 to the anode of a light emitting diode of a photocoupler 68, and a negative terminal connected to the cathode of said light emitting diode; a capacitor C5 is connected between said positive and negative terminals of the second branch. The photocoupler 68 has a phototransistor, the base of which is connected to the collector by a capacitor C6, said collector being connected to ground; the phototransistor emitter is connected to ground by a resistor 65, to a negative potential -V by a resistor 66, and to the gate G of a field effect transistor T3 whose source S is to ground and the drain D is connected by wire 53 to the diffusion circuit 13.

The switch 76 allows the attenuator to be turned on or off.

 The access circuit Ai is connected to a participant by the office to which said access circuit is connected. The input transformer TF1 therefore receives a signal from the participant, and the output transformer TF2, transmits a signal to said participant, said transmitted signal being routed by the incoming line LEi from the multiplexing circuit Mi.

 The low threshold circuit 10 considerably weakens the signals whose level is less than 200 millivolts thanks to the diodes Di. and D2 which are germanium diodes; it allows signals with a level above 200 mv to pass virtually without weakening; the resistor 23 and the capacitor C1 constitute an integrator. The circuit 10 also provides impedance matching.

The phase analyzer circuit compares the received signal, which consists of the participant's speech signal and the echo, with the signal sent to the participant and which comes from the multiplexing circuit.
Mi, this signal being at the origin of the echo in the links outside the access circuit.

 The signal delivered by each of the amplifiers 37 and 38 is a differential signal, for one of the half-waves, and the signal received from the low threshold circuit 10 for the other half-wave. The two alternations of the received signal are applied, after passing through the low threshold circuit 10 to the amplifiers 37 and 38. At the output of the level 14 adapter circuit, the signal sent is applied to the potentiometer P2, which plays the role of a divider Of voltage ; the positive alternation goes through the diode D3 and is applied to the amplifier 37, while the negative alternation goes through the diode D4 and is applied to the amplifier 38. The amplifier 37 therefore delivers for the positive alternations a signal differential which is the difference between the received signal and the transmitted signal, and for negative half-waves the received signal; the amplifier 38 delivers the positive signal for the positive half-waves and a differential signal for the negative half-waves. In the summing / suppressor circuit 12, the transistor T1 polarized at the conduction threshold by the diode D5 allows the positive half-waves to pass and blocks the negative half-waves, and the transistor T2 polarized at the conduction threshold by the diode D6 lets the negative half-waves pass and blocks the positive half-waves. The signal at point F consists only of the positive half-waves of the signals delivered by the amplifier 37 and by the negative half-waves of the signals delivered by the amplifier 38, said positive and negative half-waves each corresponding to a differential signal. ; at point F there is therefore a total differential signal, since there are two alternations therein, the level of which is lower than that of the signal received through the low threshold circuit 10, since this has been reduced by a value proportional to the level of the signal transmitted.

 The diffusion circuit 13 comprises a clipper, constituted by the resistor 36 and the diodes D7 and D8, with germanium, which attenuates the signal applied to the amplifier 39 in the event of over-modulation of this signal, the diodes operating in their conduction bend and therefore being all the more conductive as the overmodulation is stronger. At the output of amplifier 39, the signal delivered is broadcast by the outgoing line LSi to all the multiplexing circuits, except to the multiplexing circuit Mi associated with the access circuit Ai.

 The access circuit therefore delivers at the output of the reception channel, that is to say on the outgoing line LSi, a signal whose signal / noise ratio has been significantly improved by the low threshold circuit 10 which makes it possible to subtract from the signal received the fraction, of the order of 200 mv, comprising practically all the parasitic noise and in particular the echo signals which are generally of this order.

 Finally the comparison, in the phase analyzer circuit 12, between the received signal (from the low threshold circuit 10) and the transmitted signal (level adapter circuit 14) makes it possible to highlight a possible echo signal returning in phase with the received signal, and to attenuate the level thereof, it being understood that the echo signals causing an attachment of the multiconversation device are those which are in phase with the received signal.

 In the worst case, the attenuator 16 (in use) which receives a signal from the level 14 adapter circuit on transmission, decreases the level of the signal received by the amplifier 39 of the broadcast circuit 13, thus avoiding the entry into oscillations.

 The transmission path of the access circuit Ai, level adapter circuit 14, expander compressor circuit 15 and output transformer TF2 makes it possible to process the signal to be transmitted and delivered by the multiplexing circuit Mi on the incoming line LEi.

 The incoming signal is amplified by the level adapter circuit 14 by a factor of about 3, equivalent to the division by the potentiometer P1.

 The expander / compressor circuit 15 behaves as an expander, that is to say an amplifier for the signals delivered by the level adapter circuit 14, the level of which is lower than the conduction voltage of the diodes D9 and D10 which are diodes silicon; for these signals the amplification coefficient is of the order of 3.

 For the signals whose level is higher than the conduction voltage of the diodes D9, D10, the gain of the amplifier 49 decreases and this all the more the higher the level of these signals. The expander / compressor circuit 15 therefore tends to equalize the levels of the incoming signals (via the incoming line LEi) which contributes to the stability of the multiconversation device, since the signal emitted by the access circuit is at the origin of the echo signal .

 The level adapter circuit 14 flows into the diode bridge of the attenuator 16 (when it is in service), and the signal collected at the terminals of the capacitor C5 controls the photocoupler 68, the conduction of which is a function of said signal at bounds of C5; the potential of the gate of transistor T3 approaches that of ground, all the more so as the signal at the terminals of C5 is higher. The transistor T3 operates as a voltage divider, its drain / source resistance decreasing; the signal delivered by the cursor of the potentiometer P1 to the amplifier 39 of the diffusion circuit 13 is further attenuated, before being sent to the multiplexers by the outgoing line LSi.

 FIG. 3 schematically represents a multiplexing circuit Mi; each multiplexing circuit comprises an analog multiplexer mx, an output amplifier 60, and a potentiometer 63.

 The analog multiplexer comprises a decoder 61 having four inputs a, b, c, d corresponding to the outputs A, B, C, D of the counter 2 of the distributor 1, FIG. 1, the counter and the decoder being connected by the bus BC. The multiplexer mx has n-l inputs, 01 to On-l each connected to an access circuit A1 to An, by the outgoing lines LSi to LSn, except to the access circuit Mi; the outgoing line LSi is therefore not connected to an input of the multiplexer mx of the multiplexing circuit Mi.

Each input of the mx multiplexer is connected, through a switch, represented here in the form of a contact, to a line 62 itself connected to ground by the potentiometer 63; the potentiometer cursor is connected to a positive input of amplifier 60, a negative input of which is connected to ground; the output of amplifier 60 is connected to the access circuit Ai by the incoming line LEi.

 As previously indicated, an access circuit Ai is connected by its outgoing line LSi to the multiplexing circuits M1 to Mn except to the multiplexing circuit Mi. But moreover, each access circuit is connected to a different input from the multiplexers.

 If for example we have an = 17 access circuit and n = 17 multiplexing circuits, with nl = 16 inputs for each analog multiplexer mx, the inputs of the multiplexing circuits are connected for example as indicated below - inputs 01 to 016 of the multiplexing circuit M1 are connected to the access circuits 2, 3, 4, 5 16, 17, respectively - the inputs 01 to 016 of the multiplexing circuit M2 are connected to the access circuits 3, 4, 5 .. .16, 17, 1, respectively, - the inputs 01 to 016 of the multiplexing circuit M3 are connected to the access circuits 4, 5, 6, 7, .... 17, 1, 2, respectively, and so continued, - the inputs 01 to 016 of the multiplexing circuit M16 are connected to the access circuits 17, 1, 2 13, 14, 15, respectively, - and the inputs 01 to 016 of the multiplexing circuit M17 are connected to the circuits d 'access 1, 2, 3 14, 15, 16, respectively.

 In each analog multiplexer the decoder delivers, for example, addresses with a duration of 1.6 microseconds, and two successive addresses are separated by a time of 400 nanoseconds.

 At each address, the multiplexer delivers a different sample on line 62, a sample which is found on the outgoing line LSi.

Each input is therefore addressed every 16 addresses, that is to say once per cycle, a cycle having a duration of 32 microseconds.

 With the connection indicated above between the access circuits and the inputs of the multiplexers, the signal of a given access circuit is sampled in the multiplexers at a different time. Thus the access circuit Al is connected to the input 01 of M17, to the input 02 of M16, to the input 03 of M15, ... to the input 015 of M3 and to the input 016 M2; it is not connected to the multiplexing circuit Mi, as has been said.

 In this way each access circuit A2 to A17 receives a sample of the signal delivered by the access circuit A1, but at a different time, which contributes to the reduction of the echo signal which would be much greater if all the access circuits simultaneously received the same sample. What has just been described for the sampling of the signal delivered by the access circuit A1 is valid for the signals of all the access circuits; in the multiplexers the signal from an access circuit Ai is sampled at different times.

 The number of access circuits, therefore multiplexing circuits can of course be different from n = 17; the -number of entry of each mx multiplexer is at least equal to n-l, and if it is higher the other entries are not used.

 Similarly, the duration of the addresses delivered by the decoder can be different from 1.6 microseconds and the time separating two successive addresses can be different from 400 nanoseconds but it is preferable to increase this time rather than to decrease it which would strengthen the signal d 'echo.

 The connections between the access circuits and the inputs of the multiplexing circuits can of course be different from those given above by way of example, subject to respecting the condition indicated, namely that the signal delivered by a circuit d the access must be sampled at different times; this requires that each outgoing line LSi be connected to different inputs of the multiplexers.

Claims (10)

1 / Multiconversation device comprising n access circuits (Al to An) connected to a central, each access circuit comprising a reception channel having an input connected to the central and an output, a transmission channel having an input and an output connected to the central, characterized in that it comprises n multiplexing circuits (M1 to Mn), each multiplexing circuit being associated with an access circuit and having nl inputs and an output, that each access circuit has the input of its send channel connected by an incoming line (LE1 to LEn) to the output of the multiplexing circuit with which it is associated, and the output of its receive channel connected by an outgoing line (LS1 to LSn) to an input of each circuit multiplexing, except that with which it is associated, and that a distributor (1) is connected by a bus (BC) to the multiplexing circuits, said distributor cyclically delivering nl addresses. 2 / Multiconversation device according to claim 1, characterized in that each multiplexing circuit comprises an analog multiplexer (mx) and an output amplifier (60), said multiplexer having nl inputs which constitute the inputs of the multiplexing circuit and a decoder (61) connected to the bus (BC), that the output of the multiplexer is connected by a line (62) to a voltage divider (63), and that the amplifier has an input connected to the voltage divider, another input connected to ground and an output which constitutes the output of the multiplexing circuit connected to an outgoing line (LS1 to LSn). 3 / Multiconversation device according to one of claims 1 and 2, characterized in that each access circuit is connected to a different input from the multiplexing circuits. 4 / Multiconversation device according to claim 1, characterized in that the transmission channel of each access circuit (Ai) comprises a level adapter circuit (14) connected at input to an incoming line (LEi), an expander circuit / compressor (15) connected at input to the level adapter circuit and an output transformer (TF2) connected at input to the expander / compressor circuit and at output to the office, and that the reception channel of each access circuit comprises a transformer input (TF1) connected to the office input, a low threshold circuit (10) connected to the input transformer input, a phase analyzer circuit (11) having an input connected to the output of the low threshold circuit (10) and another input connected at the output of the level adapter circuit (14), a summing / suppressing circuit (12) connected at the input to the phase analyzer circuit (11) and a diffusion circuit (13) connected at the input to the summing / suppressing circuit (12) and at output to an outgoing line (LSi). 5 / Multiconversation device according to claim 4, characterized in that the low threshold circuit (10) comprises a first (21), a second (22), a third (23) resistors, two diodes (D1, D2) and a capacitor (C1), the first resistor (21) being connected on the one hand to ground and on the other hand to the input transformer (TF1), the second resistor (22) being connected between the first (21) and the third (23) resistors, one end of which is connected to ground, each diode being connected in parallel on the second resistor (22) the two diodes being mounted head to tail, and the capacitor (C1) being in parallel on the third resistor (23), the output of the low threshold circuit (10) being a point common to the second (22) and third (23) resistors. 6 / Apparatus according to claim 4, characterized in that the phase analyzer circuit (11) comprises a first (37) and a second (38) amplifier each having a positive input connected at the output of the low threshold circuit (10) , each amplifier having a negative input and an output connected by a resistor (28, 29), an adjustable voltage divider (P2) connected on the one hand to ground and on the other hand at the output of the level adapter circuit (14 ), that the voltage divider is connected on the one hand to an anode of a first diode (D3) having its cathode connected to the negative input of the first amplifier (37) by a first resistor (24) and to ground by a second resistor (26) and on the other hand to a cathode of a second diode (D4) having an anode connected to the negative input of the second amplifier (38) by a third resistor (25) and to ground by a fourth resistor (27), and that the outputs of the first and second amplifiers constitute a first era and a second phase analyzer circuit outputs (11). 7 / Multiconversation device according to claim 4, characterized in that the summing / suppressor circuit (12) comprises a first transistor (T1) of PNP type, a second transistor (T2) of NPN type, and a voltage divider (P1 ) adjustable, that the first transistor (T1) has an emitter connected to a first output of the phase analyzer circuit (11) and a base connected to ground by a first diode (D5) and to a positive potential (+ V) by a first resistor (30), that the second transistor (T2) has an emitter connected to a second output of the phase analyzer circuit (11) and a base connected to ground by a second diode (D6) and to a negative potential ( -V) by a second resistor (31), that a collector of the first transistor and a collector of the second transistor are each connected by a third (32) and a fourth (33) resistors at a common point (F) connected to the ground on the one hand by a fifth resistance (34) and on the other hand by a sixth resistance nce (35) in series with said adjustable voltage divider (P1), and that an adjustable point of said voltage divider constitutes an output of the summing / suppressor circuit. 8 / Multiconversation device according to claim 4, characterized in that the diffusion circuit (13) comprises an amplifier (39) and a clipping circuit, that the amplifier has a positive input connected by two resistors in series (51 , 52) at the output of the summing / suppressor circuit (12), a negative input and an output connected directly, that the clipping circuit is connected on the one hand to the positive input of the amplifier by the two resistors in series and d on the other hand to ground and comprises a resistor (36) in series with two diodes (D7, D8) mounted head to tail, and that the output of the amplifier (39) is connected to the outgoing line (LSi). 9 / Multiconversation device according to claim 4, characterized in that the expander / compressor circuit (15) comprises an amplifier (49), a first (D9) and a second (D10) diodes, that a negative input of the amplifier is connected by a first resistor (43) at the output of the level adapter circuit, that a positive input of the amplifier is connected on the one hand to ground by a second resistor (45) and on the other hand at output the level adapter circuit by a third resistor (44) in series with the first and second diodes mounted head to tail, a fourth resistor (46) is connected between the negative input and an output of the amplifier, and that said amplifier output is connected by a fifth resistor (47) to the output transformer (TF2). 10 / Multiconversation device according to claim 8, characterized in that an attenuator (16) is connected between an output of the level adapter circuit (14) and a point common to the two resistors (51, 52) in series of the circuit diffusion, said attenuator comprising a switch (76) for switching on or off, said attenuator weakening the signal delivered by the summing / suppressor circuit (12) to the diffusion circuit (13), the weakening being a function of the signal delivered by the level adapter circuit (14).