DE1223428B - Circuit arrangement for telecommunication, especially telephone systems with two-way connections - Google Patents

Description

Circuit arrangement for telecommunications, in particular telephone systems with two-way connections The invention relates to a circuit arrangement for telecommunications, in particular telephone systems with two-way connections. Its subject matter is in particular those intermediate connections in which non-linear switching elements, dependent on the current direction and of opposite polarity for the two subscriber stations, are inserted into the subscriber-specific branch lines. These switching elements - as such, low-capacitance rectifier diodes are usually used - are used for the alternative connection of the individual branch lines to the common connecting line, i. H. to guarantee the secret traffic, as well as to identify the two subscriber stations.

The known two-way connection circuits of this type have various disadvantages: Above all, this includes eavesdropping on an existing call connection by the subscriber station not involved in this connection, which is possible by means of suitable switching measures on the speech wires leading to this subscriber station. In Fig. 1 this possibility of listening is indicated - it is assumed that there is a call connection for the subscriber station Tnl. Then the rectifiers D 1 and D 2 inserted into his subscriber-specific branch line are polarized in the forward direction by the supply voltage B U applied to the common connecting line VL in the exchange. In this state, the subscriber station Tn2 is disconnected from the common connecting line VL, since the rectifiers D 3 and D 4 are used in the reverse direction. If, however, the wire b 2 is connected to the ground potential at this subscriber point, the rectifier D 3 also enters the pass band. so that the call connection at the subscriber station Tn 2 can be tapped.

The invention has set itself the task of addressing these and other disadvantages to avoid the known arrangements. It also relates to two-way connections, where in the subscriber-specific branch lines the secret traffic, the Identification and, if necessary, the call current transmission serving the direction of the current non-linear switching elements of opposite for the two subscriber stations Polarity are inserted, and is characterized in that at least one, the mentioned switching elements inserted into each of the subscriber-specific branch lines has a controllable bistable current-voltage characteristic and that the control input this switching element is in connection with the other speech wire.

Such switching elements with controllable bistable current-voltage characteristics can be semiconductor current gates, for example. A "bistable current-voltage characteristic curve" means that the switching element in question has operating points of high and low differential resistance and that the latter can only be reached after a voltage threshold has been exceeded. In general, the characteristic point marked by this voltage threshold is followed by a part of the characteristic curve with a negative slope, i. In other words, as the current strength increases, the voltage drop across the switching element decreases again. As a result, the existing operating points with low differential resistance are stable operating points.

As an electrically bistable two-terminal network, glow lamps are as well as above all Four-layer diodes became known. When in an arrangement according to the invention to be used controllable electrically bistable switching elements can be described Voltage threshold by supplying a suitable control current or a control voltage are decreased, so that the family of characteristics of such a switching element from a There is a host of so-called ignition voltage characteristics. As soon as a stable working point is reached with low differential resistance, the behavior is this Switching elements generally no longer differ from those prevailing at its control input Voltage and current conditions dependent. In addition to the semiconductor current gates mentioned are mainly cold cathode tubes and thyratrons as controllable electrically bistable Switching elements become known. In the designed according to the invention Arrangement, it is no longer possible to connect to the speech lines of the this subscriber station not involved in an existing call connection Intercept connection. That into the voice of the participant station that is not involved That is, the controllable switching element inserted into the leading branch line does not receive any suitable control voltage so that the voltage threshold to be exceeded if you have a low differential operating point required for eavesdropping Resistance wants to achieve is greater than the voltage caused by the connection to earth is available on the switching element.

The invention can be implemented particularly easily by inserting a controllable, electrically bistable switching element into the one voice wire of each branch line , the control input of which is connected to the other voice wire, while the usual rectifier with the one required to feed the subscriber station is in this Polarity is looped in.

However, it is also possible to have a controllable one in each speech artery Insert switching element and connect their control inputs with each other. the The polarity of these two switching elements is of course to be selected again that they are in their low-resistance state for currents of the direction of the supply current the relevant subscriber station are permeable. Merbei shows that the two Switching elements must have a structure that is complementary to one another, then both can be fed from the exchange with suitable control currents.

If one wants to also prevent in the described circuit arrangements, -that a - listening to the non-participating subscriber station enables thereby that inserted into the speech wires leading to this subscriber station branch line switching elements controlled by applying an external voltage of suitable polarity and size in its low-resistance region can be, this is made possible according to a development of the invention in that a voltage divider consisting of two series-connected voltage-limiting non-linear resistors is connected in parallel to each subscriber station in a bridge to the two speech wires, the center of which is connected to earth potential. Voltage limit to select the non-linear resistors so that it is below the voltage by which the controllable switching elements may be placed in its low-impedance state when no control voltage respectively to them, '- This is. no control current is effective.

Another problem with two-way connections as described above Type consists in the transmission of the alternating ringing voltage. The alternating ringing voltage is in the call state of the voltage of the office battery superimposed, its polarity in turn is decisive for the selection of the employee position. The wake-up capacitor in the subscriber station is charged to a voltage which, taken absolutely, is equal to the sum of the office battery voltage and the amplitude of the alternating ringing voltage and its polarity through the forward direction of the non-linear switching elements inserted in the relevant branch line is determined. If the voltage prevailing across these non-linear switching elements however, their sign is reversed in the further course of the ringing current transmission this demands in the reverse direction and prevent the alarm capacitor from discharging or recharging in the usual way. A further development of the invention therefore proposes parallel to the non-linear switching elements looped into the individual speech wires further controllable electrically bistable switching elements with opposite polarity to be arranged, which are controlled by the voltage of the alarm clock capacitor and in an area of low differential resistance as soon as they pass voltage occurring after it has reversed its sign for the reasons mentioned above has reached a corresponding value.

A circuit that meets these requirements can, for example be realized in such a way that each of the individual participants is in at least one speech artery Branch lines a pair of reverse-parallel connected, direction-dependent controllable Switching elements with bistable current-voltage characteristic is inserted, their control inputs be in communication with the other vein.

Is the arrangement made so that the Branch line a pair of such controllable switching elements is inserted, wherein the switching elements in the one voice wire turn one opposite the structure of the the switching element inserted into the other speech vein have a complementary structure, so the control input is each of the switching elements inserted into a voice wire with the control input of that one of the switching elements inserted in the other speech wire to connect that with respect to one of the two series-connected Speech wires running circuit (e.g. the supply circuit of the relevant Subscriber station) has the same polarity.

In addition to the already mentioned FIG. 1, which shows the possibility of eavesdropping with normal relay-less two-way connections, exemplary embodiments of the invention are shown. The controllable non-linear switching elements used are shown as semiconductor current gates. They can of course be replaced by other components that have a similar set of current-voltage characteristics. Such a family of characteristics is shown in FIG. 2: The voltage U prevailing between the cathode and anode is plotted on the ordinate axis, and the current 1 flowing through these electrodes is plotted on the abscissa axis. The control currents I, t serve as parameters. It can be seen that this family of characteristics describes the behavior of a switching element that has stable operating points of high and low differential resistance. It can also be seen that the latter can only be reached after a voltage threshold has been exceeded, the value of which depends on the magnitude of the control current.

F i g. 3 shows a simple way of implementing the invention: the current gates Sl and S 2 respectively are inserted into the speech wires A 1 and A 2 of the two branch lines. Your control input is connected to the other voice wire via a (high-resistance) resistor. This other voice line contains the usual rectifier. At rest. state, the only schematically indicated shared transmission in the exchange applies a starting alternating voltage U "to the common connecting line VL. The two current ports S 1 and S 2 thus receive a control current alternately and periodically can reach low-resistance area as soon as the subscriber loop in question is closed and the required voltage appears at the power gate via the rectifier present in the other voice wire If the connection request originated from subscriber station Tnl, this feed current source has the polarity shown in FIG. 3. If an attempt is now made at subscriber station Tn 2, which is not involved in the existing connection, to listen to the conversation by applying earth, in contrast to the circuit according to FIG. 1 no suitable circuit is established, since the current gate S2 receives no control current and therefore the voltage threshold to be exceeded is higher than the available voltage.

In the circuit according to FIG. 4, the diodes D 1 and D 2 are replaced by two more current gates S 3 and S 4. These have a structure that is complementary to the structure of the current gates S 1 and S 2, i. That is, while those are controlled by the current caused by a positive voltage acting between the control input and the cathode, they receive a suitable control current if a negative voltage is active between the control input and the anode. If the potential of wire a of the common connecting line YI- is negative compared to that of wire b , the two current ports SI and S3 are influenced in such a way that they can become permeable with low resistance as soon as the subscriber loop at subscriber station Tnl is closed. Listening to a call by applying ground potential to a voice wire of the subscriber station that is not involved is not possible with this circuit either. In addition, however, a voltage divider consisting of two voltage-limiting non-linear resistors Gl, G2 or G3, G4 is connected in a bridge to each pair of speech wires, the center of which is grounded and which prevents the current gates inserted into the branch line of the subscriber station not involved from being applied by applying an external voltage Can be "ignited". Since the voltage limit of these non-linear resistors is smaller than the voltage threshold of the current ports when their control inputs are de-energized, a voltage of the required magnitude cannot occur at these current ports at all.

F i g. 5 shows a circuit in which there are two current gates connected in anti-parallel in the one voice wire of each branch line. While the current gate S 1 is controlled by the phase of the starting alternating voltage intended for the subscriber station Tn 1 or by the same polarized DC supply voltage, the current gate S3 enables the discharge or reloading of the alarm capacitor in the ringing state: In this ringing state, the voltage of the A ringing alternating voltage superimposed on the exchange battery. If the voltage of the office battery has the indicated polarity and if it is assumed that the ringing alternating voltage source starts sending a negative half-wave at the time under consideration, the alarm clock at the subscriber station Tnl can be charged to the voltage corresponding to the sum of the office battery voltage and the amplitude of the ringing alternating voltage . However, if the sum mentioned exceeds its maximum value, the sign of the voltage applied to the two current ports 1 and S3 is reversed. The power gate Sl is then de-energized. By contrast, a control current fed by the charge of the wake-up capacitor can flow via the (high-resistance) resistor R 3 for the current gate S3. This control current, together with the voltage applied to this current gate, which now has the appropriate polarity, causes this current gate S 3 to become permeable and an Ent or. Reloading of the alarm clock capacitor allows.

While the circuit described last does not offer any protection against eavesdropping on a call connection at the subscriber station that is not involved, since the one voice wire of each branch line does not contain any blocking elements, such eavesdropping with the circuit according to FIG . 6, in which a further pair of antiparallel-connected current gates is inserted into this speech artery, made impossible.

The mode of operation of this circuit results directly from a combination of the two circuits according to FIG. 4 and FIG. 5.

Claims (2)

Claims: 1. Circuit arrangement for Ferninelde-, in particular telephone systems with two-way connections, in which in the subscriber-specific branch lines the secret traffic, the identification and optionally the ringing current transmission serving current direction-dependent switching elements of opposite polarity for the two subscriber stations are inserted, d a - characterized in that at least one of the mentioned switching elements inserted into each of the subscriber-specific branch lines has a controllable bistable current voltage curve and that the control input of this switching element is connected to the respective other voice wire. 2. A circuit arrangement according to claim 1, characterized in that a switching element with a controllable bistable characteristic is inserted into the one speech wire of each branch line, the control input of which is in communication with the other speech wire, and that in that section of this other speech wire that leads from this connection point to the relevant subscriber station runs, a rectifier is inserted, which has the same polarity as the aforementioned controllable switching element with respect to a circuit running over the two series-connected speech arenas (e.g. the supply circuit). 3. A circuit arrangement according to claim 1, characterized in that a switching element with controllable bistable characteristic is inserted into both speech wires of each branch line, one of which has a structure that is complementary to the structure of the other, that these two switching elements are in their low-resistance state for currents are permeable from the direction of the feed current, that their two control inputs are connected to one another and are arranged in such a way that they can be influenced by a voltage applied to the common connecting line. 4. Circuit arrangement according to claim 1, characterized in that a pair of anti-parallel connected current-direction-dependent controllable switching elements with bistable current-voltage characteristic is inserted into a speech line of each of the subscriber-specific branch lines, the control inputs of which are connected to the other speech line. 5. Circuit arrangement according to claim 1 or 3, characterized in that a pair of antiparallel-connected switching elements controllable in the manner mentioned is inserted into both speech wires of each branch line, that the switching elements in one speech wire have a gap above the structure of the switching elements inserted into the other speech wire of the same branch line have a complementary structure and that the control inputs of the switching elements inserted in one speech wire are connected to the control inputs of those switching elements inserted in the other speech wire which are connected to a circuit (e.g. the supply circuit of the subscriber station concerned) running over the two speech wires connected in series ) have the same polarity. 6. Circuit arrangement according to one of the preceding claims, characterized in that a voltage divider consisting of two series-connected voltage-limiting non-linear resistors is connected in parallel to each subscriber station in a bridge to the two speech units leading to this subscriber station, the center point of which is connected to ground potential, the voltage limit this non-linear resistance is chosen so that it is below the voltage through which the controllable switching elements. can be placed in a range of low differential resistance if no control voltage or no control current acts on them. 7. Circuit arrangement according to one of the preceding claims, characterized in that said controllable switching elements are semiconductor current gates.