DE1186113B - Circuit arrangement for telephone extension systems - Google Patents

Description

Circuit arrangement for telephone private branch exchanges There are telephone private branch exchanges known, in which all extensions a trunk group is common, with its Identification lines the individual extensions are individually connected and through which an extension is identified and its authorization to the various Transport opportunities can be determined. The connection from the extension to the common line bundle takes place through coupling diodes, which are from a routing point assigned to the subscriber to the respective identification lines in question (I and B lines) can be marshalled. An output is also used as a junction point circuit used for other tasks, e.g. B. the d-wire output of the subscriber coupler used, which is used at the same time for other switching tasks, e.g. B. to hold the coupling relay involved in establishing a connection is then available Identification only a small voltage swing available, which is not sufficient in order to use the bundle of I and B lines in the known arrangement as a relay trained evaluation and display switching means to operate, the with each identification request be switched on ready to receive.

The invention aims, also in these cases, the shared use for to enable other switching tasks to reliably identify the individual extensions. This is achieved by the invention in that the identification lines common to all participants each contain a bistable storage element as evaluation switching means and a defined potential are biased so that the coupling diodes so long are blocked as marking is not required.

An embodiment of the invention is shown in the drawing. It shows F i g. 1 shows the basic circuit arrangement of some identification lines and some participants, F i g. 2 shows a circuit arrangement of a bistable storage element, F i g. 3 shows another circuit arrangement of a bistable memory element, F i G. 4 shows a circuit arrangement for converting decadic identifiers into binary Identification by means of several bistable storage elements.

In the case of the in FIG. 1, several identification lines KL are provided, which are designated KL 1, KL 2 ... KL x . Each of these identification lines is connected to a bistable memory element in the form of a toroidal core K, so that a current flow in the identification line is able to change the magnetization state of the associated toroidal core K.

One end of the identification line KL is biased to a specific voltage value via a voltage divider - formed from one of the resistors Re, one of the decoupling diodes De and the resistor RV 1 and a Zener diode Z1. The resistor RV 1 and the Zener diode Z1 form a voltage divider which has a certain negative voltage value at the connection point between the resistor and the Zener diode. This negative voltage value is fed to each of the identification lines KL via the decoupling diodes De.

The individual extensions of the telephone extension systems are connected to the other branch of the identification lines KL, specifically a jumper point dT assigned to the extension. In Fig. 1 shows the shunting points dT 1, dT 2 and dT 3 of three different participants. This junction point is at positive potential via a resistor RT. The connection of the jumper point with one or more identification lines KL takes place via coupling diodes Dr.

The jumper point dT of a subscriber can be in a circuit that is also used for other purposes. For the jumper point dT 1 it is indicated, for example by the contacts KA, KB, KC, that this jumper point dT 1 lies in an auxiliary wire ld which is connected to an internal connection set IVS via three coupling stages. In the circuit via the pilot wire ld, the relays of the coupling stage are to be kept energized at the same time. For this purpose, a relay M is connected to the pilot wire 1d via a contact of the coupling stage in each coupling stage.

In the operating state, the pilot wire 1d is connected to the internal connection set IVS by means of a contact F 1 to a voltage divider which is formed from the resistor R V2 and a Zener diode Z2. The connection point of resistor R V2 and Zener diode Z2 carries a certain negative voltage value, which allows an excitation current to flow for the holding relays MA, MB and MC of the three coupling stages. The negative potential occurring at the jumper point dT 1 has the same level as the negative potential at the other end of the identification lines KL, so that no current flows through the identification lines and the bistable memory elements K are not influenced.

If the identification of a subscriber is to be conveyed, an increased negative potential is temporarily connected to terminal I in the internal connection set IVS to which the subscriber in question is connected. This increased negative potential penetrates the coupling diodes Dr and causes the decoupling diodes De to be blocked at the other end of the identification lines. There is therefore a current flow via the identification line and the resistor Re connected to it, which reverses the bistable storage element K1, KZ and Kx.

In the case of the in FIG. 2, the magnetic core Kx of the identification line KLx is constantly biased according to the one remanence state by a winding fed via the resistor Re. The interrogation pulse running over the identification line KZ x alone cannot switch the magnetization of the core to the other remanence state. However, the interrogation pulse is supported by a further pulse which flows in a circuit controlled by the transistor TRa as soon as a negative pulse is applied to the terminal LKI. This negative pulse at terminal LKI occurs synchronously with the negative pulse at terminal 1 of the internal connection set IVS. Both pulses together magnetize the core Kx so strongly that its state of magnetization changes. As a result, a pulse is generated in the winding connected to the transistor TRb, which pulse allows an identification potential to appear at the terminal LKA.

In the case of the in FIG. 3, the core Kx is reversed by the interrogation pulse on the line KL x in a direction in which the pulse generated in the evaluation winding cannot open the transistor TRb, so that with this reversal no evaluation potential occurs at the terminal LKA. Only when a read pulse is applied to terminal LLI at a later point in time is core Kx returned to its initial state, and this change in the state of magnetization causes transistor TRb to open and thus an evaluation potential at terminal LKA.

The identification lines KL can be used for identification in a known manner serve the number of a subscriber. An identification line can be used directly be assigned a decadic numerical value, so that to identify ten Participants ten identification lines are required. Using several binary Storage elements can also be encoded so that the representation of a digit value takes place immediately in the form of a binary code.

The in F i g. .4 circuit arrangement shown shows, for example, the connection of the jumper points dT 1 to dT 10 of ten participants with ten auxiliary lines HL 1 to HL 10. These ten auxiliary lines HL are assigned four memory cores KX 1, KX 2, KX 4, KX8, and the individual auxiliary lines HL ... are linked to several memory cores in such a way that z. B. in the dual code several memory cores to represent a digit value can be influenced. For example, the auxiliary line HL 5 is linked to the memory cores KX 1 and KX4, so that both are influenced by an interrogation pulse. The auxiliary line HL7 is linked, for example, to the memory cores KX 1, KX 4 and KX2, so that these three cores are influenced by an interrogation pulse. In this way, the number of binary storage elements can be reduced significantly in a known manner.

Should, for example, in a telephone branch exchange with several Hundreds of extensions three-digit numbers are identified, so are for this in a known manner only three times four toroidal cores K, each in an arrangement according to F i G. 4 required. It can also be used to identify the various permissions the individual extensions are provided with additional identification lines with toroidal cores with which the jumper points of the individual extensions are connected accordingly are.

Claims (7)

Claims: 1. Circuit arrangement for telephone extension systems for the identification of individual subscriber connections by means of a bundle of identification lines which are common to all subscribers and which are coupled via coupling diodes and which lead to evaluation and display switching means which are switched on ready to receive at every identification request, characterized in that the identification lines common to all participants (KL ) contain a bistable storage element (K1 to Kx) as evaluation switching means and are biased to a defined potential in such a way that the coupling diodes (Dr ... ) are blocked as long as identification is not required. 2. Circuit arrangement according to claim 1, characterized in that a requirement potential applied to the connecting device (IVS) for identification penetrates the coupling diode (Dr) and enables the bistable storage element (K ... ) to be influenced. 3. Circuit arrangement according to claim 1 and 2, characterized in that the voltage ratios both ends of each identification line (KZ) fixed via Zener diodes (Z I and Z2) are. 4. Circuit arrangement according to claim 1, characterized in that that the bias circuit of the identification lines (KL) is a decoupling diode (De) contains, which is blocked by the request potential. 5. Circuit arrangement according to claim 1, characterized in that each bistable element (K) under one Preload is available and only through coincident pulses on the identification line (KL) and a clock can be reversed. 6. Circuit arrangement according to claim 1 and 5, characterized in that the evaluation of the reversal of a core when reversing takes place under the influence of the interrogation pulse. 7. Circuit arrangement according to claim 1 and 5, characterized in that the evaluation of the reversal of a core when it is returned to the starting position takes place under the influence of a read pulse. B. Circuit arrangement according to claim 1, characterized in that auxiliary identification lines (HL 1 to HL 10) are coded and connected to several bistable memory elements (KX1 to KX 8) so that the decimal value of a subscriber line is identified by influencing several binary memory elements in code representation. Documents considered: German Auslegeschrift No. 1103 988.