DE932024C - Circuit arrangement for conference systems - Google Patents

Description

Circuit arrangement for conference systems The invention relates to a Circuit arrangement for conference systems, in which the connection of the individual Subscriber stations to the common connection line takes place individually.

The task of such arrangements is that all of be able to hear and speak to the microphone units involved in a conference call. If the number of subscriber stations is low, they can be connected in parallel be connected to each other. However, there will be an understanding in the case of a plurality made impossible by subscriber stations due to mismatching and current branching. Mismatching and back hearing, which also occurs in this case, can be caused by compensating devices can be balanced, but attenuation still occurs due to the current branching and transformer losses.

The invention aims at the disadvantages outlined above in a conference system Avoid any size. There should always be a good way of communicating regardless of whether there are more or fewer participants in a conference call participate. According to the invention this is achieved in that the common connecting device a negative impedance is assigned and dominated by the subscriber lines Switching means the ratio between the negative impedance and the total impedance of all stations involved in a conference call constant. According to Another embodiment of the invention consist of the switching means for keeping constant the ratio of negative impedance to total impedance the number of subscriber stations corresponding apparent resistances, of which each corresponds to the impedance of the station, and it is over the subscriber line individually assigned switching means, e.g. B. Relay, to the common connection line turned on.

The value of the negative impedance is then equal to the value of all station resistances.

According to a further embodiment of the invention, they are individual to the subscriber lines associated apparent resistances then usually with the common connecting device connected if the corresponding subscriber station does not connect to it Has.

The stations are controlled via the switching means assigned to the stations and the negative impedance connected in parallel to the common connecting line turned on.

According to a further embodiment of the invention, the negative impedance changed by switching means controlled by the subscriber stations in such a way that that in each case impedances, which influence the value of the negative impedance, can only be switched on when the corresponding subscriber station is connected has switched on the common connection line.

The invention is shown below with reference to some of the drawings Embodiments described in more detail. It shows Fig. I the schematic structure a conference system, Figure 2 the conference system, in which the negative impedance by a positive impedance and a four-pole network, which is the sign of the impedance changes, is obtained, Fig. 3 shows a four-pole network with a negative feedback amplifier,.

Fig. ¢ the negative feedback amplifier in more detailed circuit details, Fig. 5 and 6 circuit details of a conference system with parallel to a common one Line switched subscriber stations, FIG. 7 a conference system with in series switched stations, Fig. 8 the schematic adaptation with the negative impedance and FIGS. 9 and 10 details for the conference system with series-connected Stations.

The overall mode of operation of the conference system will first be described with reference to FIG. Assume that the network contains three stations 1, 2 and 5. The stations i and 2 are connected to each other via the lines 3 and q. tied together. Station 5 is connected in parallel with a negative impedance 6. It should also be assumed that the impedance Z is the same for stations 1, 2 and 5 occurring in the description. If the absolute value of the negative impedance 6 is chosen to be equal to the impedance Z of stations 1, 2 and 5, the total impedance of station 5 and impedance 6 is given according to the formula Z (-Z) ZZ.

This impedance has an infinite value. Since he is shunted with lines 3 and ¢, station i can connect to station 2 without any interference speak through station 5 and impedance 6. -The station i is with completed the impedance of the station i to which it is adapted, and vice versa. The sidetracking circuits of both stations are not affected. station 5 is parallel to station i and therefore has the same conditions as the latter. She can speak to station 1 and 2 without being influenced. Additional stations can connected in parallel to station 5, provided that the impedance of all these stations has an absolute value that is equal to the negative impedance is.

The negative impedance 6 can, as shown in Fig. 2, by combining an impedance 7, e.g. B. resistor, coil, etc., with a four-pole network 8, which reverses the value of the impedance will.

The quadrupole network can be in various ways, such as. B. according to Fig. 3, be constructed.

In this figure a negative feedback amplifier 9 is shown, its output to the input io via the impedance 7, line 14 and impedance 15 is connected.

The following terms should apply: z for the impedance between terminals io and i i, e the voltage between these terminals, I the current, which flows in the direction io, 15, = q., 13, Z is the value of the impedance 7, Zi the internal impedance of the amplifier 9, e the voltage between the terminals 12 and 1q., Z 'the value of the impedance 15, G the gain of the amplifier 9, Ge 'is the electromotive force of the amplifier between points 12 and 13.

The theory of negative feedback is well known and therefore need not be described here. We can write the following formulas: It should be assumed that in the exemplary embodiment G = 2 and ü ' = Zi. It is therefore s = -Z.

This creates a negative impedance between the terminals io and i i, the magnitude of which = Z is obtained.

The four-pole network, which is characterized by terminals io, 1r, 13, 14 is, accordingly, works as a converter of the sign of impedance.

In Figure 4 details of the four-pole network are shown. It exists essentially from a 3-stage resistance amplifier. The signal is sent to the Grid of the tube 16 is applied via the impedance 15 and comes out reinforced the anode of the first stage out, where it is in turn over to the grid of tube 18 the coupling capacitor 17 is applied. The exit of this tube is in the same Coupled to the grid of tube i9 as in the previous stage. These Tube works as a full negative feedback amplifier. Part of the output voltage is applied from point 13 through resistor 2o to the cathode of tube 1d. Of the The increase in negative feedback is determined by resistors 2o and 21. As a result of the impedance 7 between the terminals 13 and 14 on the one hand and the On the other hand, there is an amplifier circuit at the input terminals, as already described, a negative impedance, the amount of which is equal to that of the impedance 7 is.

However, this arrangement is only intended to serve as an example. It can also other amplifier circuits can be used to determine the sign of the impedance to change.

The circuits shown in Figs. 5 and 6 show more details of the rectangle in dot-dash lines in FIG.

Fig. 5 shows a practical embodiment for a constant resilient conference network, in which the various subscriber stations are connected in parallel.

The amplifier 8 and the impedance 7 are connected in parallel via a transformer 22, the contacts 231 and 232 with the impedance 30 , which is to be referred to as a simulation. 3a of such replication devices are connected to one another in parallel via points 24, 25. Such a simulation device is assigned to each station 5. The designation 23 relates to the feed relay for station 5, while 26 and 27 are the blocking capacitors for the direct current. It is assumed that all stations have hung up their handset and all relays 23 are in the idle state. All simulation devices 30 are connected to the common line via contacts 23i and 232. It is now assumed that the handsets of the various stations 5 have been removed from the cradle and are connected to the conference facility via lines 31 and 32. The relays 23 are actuated accordingly. The contacts 23i and 232 switch over, so that the simulation devices 3o are switched off and the stations 5 are connected together in parallel at points 24 and 25. The impedance 7 should be equal to Z / n, where Z is the value of the impedance of a station. All n-stations, which have an impedance value equal to the impedance 7, are connected to the amplifier 8 and the impedance 7 via the transformer 22. The transformation ratio of the transformer should be equal to i. The impedance 7 must be calculated differently for every other value. The transformer 22 separates the DC circuits and is only used to adjust the impedance. With regard to the speech streams, however, the arrangement is as if all the stations 5 are directly connected to the four-pole network 8 in parallel. The stations 5, the four-pole network 8 and the impedance 7 have an infinite impedance. If one of the stations is not connected to this circuit, e.g. B. if a participant does not wish to participate in a conference call, a simulation device 30 is switched via the contacts 23i and 232 instead of the participant's set to the common line, since the assigned relay 23 has not responded. Since the impedance of the simulation device 3o has the same value Z as that of the station, the overall conditions on the network do not change at all.

The load on the four-pole network 8 is always constant and independent how many stations are in the conference call.

A variable, resilient conference network with parallel connectable Stations will now be described with reference to FIG.

The stations are the same as in Fig.5. Each relay 23 are the contacts 23 i, 232, 233 and 234 assigned. Each station is also an impedance 7 assigned, which with the four-pole network 8 via the contacts 233, 234 and the common points 26, 27 are connected.

If the various stations have put their handsets on, so the relays are in the idle state and consequently also the contacts 23 i to 234 opened. Station 5 as well as the impedance are switched off.

If all stations are connected to the conference facility, then the corresponding relay 23 is also energized and the contacts 23 i to 234 are closed. The stations are at the common points 24 and 25 and the apparent resistances 7 interconnected at points 26 and 27. Has the impedance 7 the same Value like that of the stations, there are two sums of impedance values, each of which has a value of Z / n. These two impedances are in parallel connected via the transformer 22 and four-pole network 8, so that the same state as in the previous case is reached again. Is a station not connected, the corresponding relay remains in the idle state so that both the impedance? and the station that has been removed from the network.

The network still remains in equilibrium. The burden on that Quadrupole network 8 is variable, and the number of apparent resistors 7 is always equal to the number of stations 5. It should be noted that in this case the Impedance resistors 7 play essentially the same role as the replicators 3o of FIG. 5.

A conference network has been described above in which the different subscriber stations are connected to one another in parallel. It will now be described a conference network in which the stations are connected in series. For this purpose, FIGS. 7 to ro serve.

Fig. 7 shows a conference network in which the stations in series are switched. It is assumed that the network includes stations 1,: 2 and 5 contains. All stations are in series with a negative impedance6 switched. The stations z, 2 and 5 have the same impedance Z. If the absolute value of the negative impedance 6 is equal to the impedance Z of the stations z, 2 and 5 is done, the combination of station 5 and impedance gets 6, an impedance value given by the formula Z -I- (-Z). This Value is zero. Since the impedance between terminals 3 and ¢ is the same Is zero, stations r and 2 are in the state as if they were alone. You can speak to one another without being influenced. Station 5 can also be used with station speak r or 2. The combination formed by 5 and 6 has an impedance equal to zero, therefore the voltage between points 3 and q is also zero. equals zero. However, the current flow through all stations is the same. The network is working under normal conditions. Additional stations can be in series with the station 5 are connected provided, however, that all stations together the have the same absolute value as the negative impedance.

The negative impedance can be done in the same way as before is indicated in Fig. 2 can be obtained. Fig. 8 shows the conference network of Fig. 7, but with two stations 5 and 5a, which are connected in series, as well with the negative impedance, the combination of an impedance 7 and a Four-pole network 8, which reverses the sign of the impedance, received will.

The description of FIGS. 9 and 10 refers to the dash-dotted line Border of Fig. B.

9 shows a conference network which can be constantly loaded and in which the stations are connected in series. In this figure only two stations 5 and 5 are shown. However, the number of stations connected to the network does not matter.

Stations 5 and 5 ″ are connected to the common connecting line 28 via transformers 22 and 22a, the secondary windings of which are connected in series. As in the previous example, stations 5 and 5 ″ are connected to the voltage source via relays 23 and 23a and isolated from the transformers by capacitors 26, 27, 2,6 "and 27a. Replicators such as 30 and 30a are associated with each station. The impedance of each replica is equal to the impedance of the corresponding station is finally terminated by an impedance 7 via a four-pole network 8.

If the various stations are connected to the conference network, the corresponding relays 23 are actuated and the contacts 23 z and 231 are closed. The simulators are disconnected from the circuit and the stations 5 and 5 "are connected in series over transformers assigned to them. It is assumed that the transformation ratio of the transformers 22 and 22a is equal to z. It is also assumed that the value of the impedance 7 is equal to n XZ, where n is the number of stations and Z is the impedance of each station. Vienna again find the same conditions as those in Fig. B.

If a station does not wish to participate in the conversation, it stays that way Relay 23 in the idle state. The contact 231 switches the simulation device 3o in their place in the circuit. Because the value of the impedance of this replica device is the same as that of the station, it changes the state of the conference network nothing. The load on the four-pole network 8 always remains constant.

A mutually resilient conference network with series-connected Stations is shown in Fig. To.

Here, too, there are only two stations for the sake of clarity shown, which via transformers in a similar way as in Fig.9 to the common Line are switched on. Each station 5 is connected to the primary winding of the transformer connected via the capacitors 26 and 27. An impedance 7 is each station 5 assigned. Each relay 23 has two contacts 2231 and 232 which make up the secondary winding a transformer 22 and an impedance 7 short-circuit.

Are the participant stations connected to the conference facility, so the relays 23 of the stations are actuated. Contacts 23z and 232 are consequently open and switch the stations via the transformers and the apparent resistors 7 to the general facility. The group formation of stations 5 and 5a, Four-pole network 8 and apparent resistors7and7Q result in the same conditions as that of the B. If one of the subscriber stations is not involved in the conference call, so relay 23 of this station has dropped out and contacts 23r and 232 are closed, whereby the secondary winding of the transformer and the impedance 7 of this Station to be short-circuited.

The load on this network can therefore be changed.

The above-mentioned exemplary embodiments only partially show the possible applications the invention. It should only be pointed out that such arrangements can also be used in conference systems with loudspeaker operation, whereby the subscriber stations are replaced by amplification devices.

Claims (7)

PATENT CLAIMS: i. Circuit arrangement for conference systems in which the individual subscriber stations are connected to the common connection device individually, characterized in that the common connection device is assigned a negative impedance (7, 8; Fig. 5) and switching means (23, 3o) controlled by the subscriber lines keep the ratio between the negative impedance and the total impedance of all stations involved in a conference call constant. 2. Circuit arrangement according to claim i, characterized in that that the switching means for keeping the ratio of negative impedance constant corresponding to the total impedance from the number of subscriber stations Impedance resistances (3o) exist, each of which corresponds to the impedance of the station and individually assigned switching means via the subscriber line, z. B. relay (23) to be connected to the common connecting line. 3. Circuit arrangement according to Claim 2, characterized in that the value of the negative Impedance is equal to the value of all station impedances. 4. Circuit arrangement according to claim 3, characterized in that the subscriber lines individually associated apparent resistances then usually with the common connecting device are connected if the corresponding subscriber station is not connected to them Has. 5. Circuit arrangement according to claim 3, characterized in that over the Switching means (23) assigned to the stations, the stations and the negative impedance (7, 8; Fig. 5) connected in parallel to the common connecting line will. 6. Circuit arrangement according to claim i or i and 5, characterized in that that the negative impedance is controlled by switching means controlled by the subscriber stations (23) is changed in such a way that each apparent resistances (7; Fig.6), the affect the value of the negative impedance, can only be switched on when the corresponding subscriber station connects to the common connection line has turned on. 7. Circuit arrangement according to claim i or i to 4, characterized in that that the switching means individually assigned to the subscriber lines control the stations (5, 5a; Fig. 9, zo) connect in series to the common connection device.