DE4031214C1 - Telephone subscribers appts. circuitry with local battery supply - has repeater coil having split etc. windings so that current flows in opposed senses to prevent premagnetisation of core - Google Patents

Abstract

The circuitry transfers communications signals between an exchange of a communications network and subscriber's appts. (1), supplied from a local battery (7). A repeater coil has its input winding (5) coupled to the exchange line (2) via a decoupling capacitor (3). A first output part-winding (10) is, on one side, coupled to earth and, on the other side, to the subscriber's appts. (1). The second output part-winding is likewise to the subscriber's appts.. The other winding end of the first output part-winding (10) is connected to earth via a first current sensor (12) using a photodiode. The subscriber's appts. receives d.c. from the second output part-winding (11) and to the other winding end of the first output partial winding (10). ADVANTAGE - Prevents premagnetisation of repeater coil without using auxiliary winding or upsetting symmetry.

Description

The invention relates to a circuit arrangement for the transmission of communication signals between a switching center of a telecommunications network and one subscriber end powered by a DC power source advises that over a core having a transformer are coupled together, the input winding with the exchange, the first output part of which on the one hand with mass and on the other hand with the part slave terminal and its second partial output winding is coupled to the subscriber terminal.

Such a circuit arrangement is from the DE 37 15 552 A1 known in the communications technology Signals between a central office of a telecommunication system denetzes and a subscriber terminal (telephone set) are transmitted via a transmitter. The transmitter contains a core with an input winding that with the switching center is coupled, and an output winding with two partial windings. Between the two Output partial windings, each with one connection of the subscriber terminal is a condenser sator switched. A partial winding is still with one DC power source for supplying the subscriber terminal coupled. The DC generated by the DC power source current flows through the two output partial windings in in the same direction. To pre-magnetize the To avoid kernel that leads to distortion of the Ver message center delivered to the intermediary le leads, the transformer has an additional winding with two partial windings. Through this additional part wick  lungs the same direct current flows as through the off partial winding, but in opposite Direction.

Furthermore, DE 35 33 762 A1 is a circuit arrangement for connecting a subscriber terminal to the Subscriber line of an electrical network, for 2- to 4-wire implementation, known with fork transformer. The Fork transformer contains two input partial windings that connected via a DC decoupling capacitor are. A feed current is switched on in the middle of the fork feeds. The fork transmitter also contains two output Partial windings that are interconnected and de opposite winding connections with two each Constant current sources are connected. The two constant Current sources are used to generate a countercurrent, with whose help compensates for DC bias becomes. In addition, the connection point is at the output sub-windings a control amplifier closed. With this circuit arrangement, a Premagnetization is compensated by the output part a compen supplied by two power sources sationsstrom is supplied.

The invention has for its object a scarf arrangement for the transmission of communications technology gnale between a switching center of a telecommunications to create network and a subscriber terminal, which includes a transformer without additional winding.

This task is carried out in a circuit arrangement gangs mentioned solved in that the participant Connection of the second output part facing away from the terminal winding with a capacitor connected to ground and a terminal of the input winding is coupled and  that to the other terminal of the input winding DC power source is connected.

In the circuit arrangement according to the invention, the direct current generated by the direct current source via the Input winding of the transformer to the second output Partial winding and via the subscriber terminal to the first Partial output winding. After the flow of the direct current mes through the first output partial winding DC current derived to ground. The direct current through the two output partial windings flow in the same direction and the input winding in opposite directions. Through this Type of direct current flow through the input and Output windings will compensate the bias sation achieved without the need for an additional winding is.

The capacitor is used to transfer the analog against alternating currents (communications signals) Derive input and output windings against ground (Decoupling). This must have a low alternating current  danz have, so the symmetry of the circuit arrangement guarantee on the side of the partial output windings is accomplished. In the absence of symmetry interference induced by electric or magnetic fields effects (e.g. crosstalk).

The circuit arrangement can also be used to transmit a Call voltage can be used. For this purpose it is provided that a ringing voltage source supplying a negative alternating voltage le via a switch on the subscriber terminal facing connection of the second partial output winding is closed and that the anode of a diode with the Connection point between switch and connection of the two th partial output winding and the cathode of the diode the connection point between the capacitor and the input winding is coupled. The switch becomes dependent controlled by the current through the subscriber terminal. In Ru status - if the subscriber is not on the phone the switch closed. That from the ringing voltage source generated negative AC voltage can end to the subscriber device. As soon as the participant uses his handset of his subscriber terminal, the switch open. The diode serves to ensure that there is no alternating current to the Connection point of capacitor and input winding flows.

To measure whether a current from the ringing voltage source as also flows from the DC voltage source is between Ground and first output partial winding a first current earth tector switched. Between diode and the connection point between capacitor and input winding is still a second current detector is switched, which measures whether a Current flows from the DC power source. By the Auswer device supplied by the two current detectors Control signals can indicate different operating states  be evaluated. For example, with the help of the Stromde tectors can also be controlled by the switch. So that Current detectors the currents flowing through them little impact, they should have a low impedance exhibit. Such a current detector can be an opto coupler included, via its entrance gate to the detec current flows and its output gate is a tax signal delivers.

An embodiment of the invention is shown below based on the drawing, the scarf arrangement for the transmission of communications technology gnale between a switching center of a telecommunications network and a subscriber terminal.

The circuit arrangement shown schematically in the figure contains a subscriber terminal 1 , which is coupled for the transmission of telecommunications signals with a switching center, not shown here. The exchange is connected via connection circuits, not shown here, with a line 2 to which a connection of a decoupling capacitor 3 is connected. The other connection of the decoupling capacitor 3 is connected to a node which, on the one hand, is connected to a direct current source 4 and, on the other hand, to an input winding 5 of a transmitter 6 . The DC power source 4 contains a supply voltage source 7 and a voltage-to-current converter 8 . The supply voltage cell 7 is connected with its positive electrode to ground and with its negative electrode to a connection of the voltage-current converter 8 . The other connection of the voltage-to-current converter 8 is connected to the node which represents the connection point between the decoupling capacitor 3 and the input winding 5 . The DC power source 4 , which serves to supply the subscriber terminal 1 , must be chosen to be high-ohmic so that the impedances of the circuit arrangement are not influenced.

The transformer 6 contains a core 9 on which the input winding 5 and two output partial windings 10 and 11 are wound. The start of the winding of the first partial output winding 10 is connected to ground via a first current detector 12 . The winding end of the first output partial winding 10 is connected to one terminal of the subscriber terminal 1 and the beginning of the winding of the two th output partial winding 11 is connected to another terminal of the subscriber terminal 1 . The beginning of the winding of the input winding 5 is connected to the direct current source 4 and its winding end on the one hand to a capacitor 13 , the other connection of which is connected to ground, and on the other hand connected to the cathode of a diode 15 via a second current detector 14 . There is still a connection between the winding end of the second output partial winding 11 and the anode of the diode 15 connected. The direct current generated by the supply voltage source 4 flows through the input winding 5 , the second current detector 14 , the diode 15 to the winding end of the second partial output winding 11th The subscriber terminal 1 receives the direct current from the second partial output winding 11 and supplies this current to the start of the winding of the first partial output winding 10 . From the first output part winding 10 , the direct current flows through the first current detector 12 to ground. This type of current flow through the transformer 6 compensation for the pre-magnetization is achieved.

The capacitor 13 is used to derive the analog AC currents to be transmitted (communications signals) of the input winding 5 and the output partial windings 10 and 11 to ground. This must have a low AC impedance. A typical value is 20 µF.

The first and second current detectors 12 and 14 each contain a light-emitting light-emitting diode 16 and 17 and a phototransistor 18 and 19 each receiving the light. The anode of the light-emitting diode 16 is connected to ground and its cathode is connected to the first partial output winding 10 . The phototransistor 18 provides control signals. The cathode of the light-emitting diode 17 is connected to the capacitor 13 and the anode to the diode 15 . The phototransistor 19 also supplies control signals. The connections of the light emitting diodes 16 and 17 represent connections of an input gate and the emitter and the collector of the phototransistor 18 and 19 represent connections of an output gate.

With the winding end of the second output partial winding 11 is still a connection of a switch 20 is connected, the sen other connection to a ringing voltage source 21 is connected. The ringing voltage source 21 contains a DC voltage source 22 and an AC voltage source 23 . The positive electrode of the direct voltage source 22 is grounded and the negative electrode is connected to a connection of the switch 20 via the alternating voltage source 23 . In the closed state of the switch 20 , a ringing voltage is sent to the subscriber device 1 . If the handset on the subscriber terminal 1 is removed from the subscriber, the switch 20 is opened. The diode 15 prevents the negative AC voltage supplied by the ringing voltage source 21 from flowing through the second current detector 14 . For this purpose, the DC voltage of the DC voltage source 22 must be selected so that its voltage is greater than the voltage of the supply voltage source 7 and is greater than or equal to the peak voltage of the AC voltage source 22nd

The control signals supplied by the two current detectors 12 and 14 can be provided for evaluating operating states. The first current detector 12 detects the current from the direct current source 4 and the current generated by the ringing voltage source 21 , while the second current detector 14 only detects the current generated by the direct current source 4 . For example, the control signals of the first and second current detectors 12 and 14 can be evaluated to control the switch 20 . The impedances of the light emitting diodes 16 and 17 must be chosen to be very low, so that the currents flowing through them are not influenced.

Claims (5)

1. Circuit arrangement for the transmission of telecommunications signals between a switching center of a telecommunications network and a subscriber terminal ( 1 ) fed by a direct current source ( 4 ), which are coupled to one another via a transformer ( 6 ) having a core ( 9 ), the input winding ( 5 ) of which with the switching center, the first partial output winding ( 10 ) is coupled on the one hand to ground and on the other hand to the subscriber terminal and the second partial output winding ( 11 ) is coupled to the subscriber terminal, characterized in that the terminal facing away from the subscriber terminal ( 1 ) second output partial winding ( 11 ) is coupled to a capacitor ( 13 ) connected to ground and a connection of the input winding ( 5 ) and that the direct current source is connected to the other connection of the input winding ( 5 ). 2. Circuit arrangement according to claim 1, characterized in that a negative alternating voltage supply voltage source ( 21 ) is connected via a switch ( 20 ) to the terminal of the subscriber terminal ( 1 ) facing away from the second partial output winding ( 11 ) and that the anode one Diode ( 15 ) with the connection point between the switch and terminal of the second partial output winding ( 11 ) and the cathode of the diode ( 15 ) with the connection point between the capacitor ( 13 ) and input winding ( 5 ) is coupled. 3. A circuit arrangement according to claim 2, characterized in that a first current detector ( 12 ) is connected between ground and the first partial output winding ( 10 ). 4. Circuit arrangement according to claim 2 or 3, characterized in that a second current detector ( 14 ) is connected between the diode ( 15 ) and the connection point between the capacitor ( 13 ) and the input winding ( 5 ). 5. Circuit arrangement according to claim 3 or 4, characterized in that the current detector ( 12 , 14 ) contains an optocoupler, via the input gate of the current to be detected flows and the output gate provides a control signal.