DE3023053C2 - - Google Patents

Description

The invention relates to a circuit arrangement in the preamble of claim 1 Art. It is in particular for loop detection on telephone lines usable.

As soon as a subscriber picks up his handset, a current flows over two-wire subscriber line, which connects the telephone set to the exchange. If the subscriber called the number Subscriber dials, each dialing digit is interrupted by loops transfer. If the whole number is transferred, then so call stream is sent to the line of the called subscriber. If he then takes off his handset, it changes the one flowing in the line of the calling subscriber Current its direction. The call charge recording does it is particularly necessary to determine both these currents to identify the calling party as well to determine the start of the conversation.

There are current detection circuits with optoelectronic Couplers known with their electroluminescent Diode in the course of the local loop and one have light coupled phototransistor with this diode.

These current detection circuits have the disadvantage that only Feeding the electroluminescent diode the whole line current or a substantial fraction of it is used, so that the life of the electroluminescent diode is significant is reduced. Furthermore, the reliability is one such optoelectronic coupler for use in Telephone systems too low.

On the other hand, such an optoelectronic coupler like all solid-state circuits, a detection threshold of about 1 V; therefore it is necessary to have a resistance of insert about 100 ohms into the line, which in some cases but is not allowed.

Furthermore, such couplers are not sufficient to withstand interference spikes protected as they are on the line from the lighting network occur.

From DE-AS 26 13 590 a circuit arrangement for Evaluation of the state change when signaling (e.g. Seizing, triggering, dialing characters) on lines in telecommunications, especially telephone systems, using a Differential amplifier for which a response threshold is specified is known, in which the output signal of Differential amplifier, one opposite to the bias voltage Partial voltage is fed back into the input circuit and its Inputs each via one of two partial resistors existing and high resistance to the line resistance Resistor connected to the line circuit. To Character protection is one of the series connection one of the Main current path of a transistor lying in parallel Capacitor and one of the control current path of the transistor parallel and the loading and unloading process enabling diode existing arrangement with the Control line coupled.

These and other measures mentioned there serve to: To make evaluation more reliable with regard to interference. Electrical isolation between the line and the evaluation circuit can not. The measuring resistor cannot be arbitrary be reduced in size since there is more than one on it Diode threshold voltage must drop.

From DE-OS 25 20 975 a circuit arrangement for Detect by different current levels in the Participant loop characterized loop states in Telephone systems in which the loop currents are detected and be given to an evaluation device, in which in a resistor is arranged on the loop and the one falling on it Voltage is fed to a comparator with one of the number the non-zero current levels to be detected corresponding number of reference voltages is applied and in which a device is provided which Reference voltages one that due to external currents at the resistor caused voltage drop corresponding voltage overlaid.

With this circuit arrangement several different Loop states can be distinguished from one another. A There is also no electrical isolation from the line possible.

The object of the invention is therefore a circuit arrangement the type mentioned in the preamble of claim 1 specify only the insertion of a negligible small current measuring resistor in the subscriber line necessary that works reliably and effectively and which is protected against spikes.

This object is characterized by those in claim 1 Features resolved.

The invention is now based on an embodiment explained in more detail.

The current detection circuit according to the invention is shown in the figure and is connected to the connections A and B of a measuring resistor R 1 inserted in the telecommunication line . The telecommunication line LT can be a two-wire telephone line, for example, and the measuring resistor can have a very small value, for example 1 to 4 ohms.

The current detection circuit has a transformer TF , the first winding of which is connected via an evaluation resistor R 8 and the collector-emitter path of a pnp transistor TR to a grounded DC voltage source (- Va) . The base of the transistor TR is supplied with the pulse train of a scanning source ip via a resistor R 9 .

The second winding of the transformer TF is connected via a diode D 1 to three series resistors R 6 , R 5 and R 4 . The resistors R 4 and R 5 preferably have the same values and, for example, each have a value of 47 ohms, while the resistor R 6 can have about 10 kΩ.

The transmission ratio of the transformer TF can preferably be 1: 1.

The current detection circuit also has a first amplifier comparator AC 1 , the non-inverting input (+) of which is connected to the common connection point of the resistors R 5 and R 6 and the inverting input (-) of which is connected via a resistor R 3 to the terminal B of the line LT . The output of this comparator is coupled to the cathode of the diode D 1 via a load resistor R 7 . The load resistor R 7 can have a value of 1 kΩ; it is ten times smaller than the resistance R 6 . The comparator AC 1 receives its power supply from the second winding of the transformer TF , namely it receives a positive potential + Vd from the common connection point of the diode D 1 and the load resistor R 7 and a negative potential -Vd from the common connection point of the second winding and Resistor R 4. The current detection circuit also contains a second amplifier comparator AC 2 , whose non-inverting input (+) via a resistor R 3 to terminal B of line LT and its inverting input (-) to the common connection point of the second winding and the resistor R 4 is connected. The output of the comparator AC 2 is connected to the output of the comparator AC 1 . The comparator AC 2 also receives the supply voltage potentials + Vd and - Vd .

The two comparators AC 1 and AC 2 have outputs with open collectors. They each output an output signal of logic 0 (potential - Vd ) when the amplitude of the signal fed to their non-inverting input is less than the amplitude of the signal fed to their inverting input. Otherwise, they emit no signal at all (open output).

Furthermore, the current detection circuit comprises the resistor R3 (approximately 100 ohms) identical resistor R 2, which is the line LT and the common connection point of the resistors R 4 and R 5 between the terminal A; a capacitor C 1 is arranged between the non-inverting input of the comparator AC 2 and the common connection point of the resistors R 4 and R 5 . A sampling pulse ip is given via the resistor R 9 to the base of the transistor TR . This controls the saturation. Therefore, a current flows from earth via the first winding of the transformer TF and the evaluation resistor R 8 to the connection -Va . The amplitude of this current depends on the value of the resistor R 8 and on the value of the load on the second winding of the transformer TF .

The amplified sampling pulse is transmitted from the transformer TF to the secondary side. The potentials + Vd and - Vd are therefore fed to the feed inputs of the comparators AC 1 and AC 2 .

If no current flows via line LT , connections A and B have the same potential; the capacitor C 1 has no charge. The potential at the two connections of the capacitor C 1 is to be referred to as Vr . This potential Vr is also present at the common connection point of the resistors R 4 and R 5 , at the inverting input of the comparator AC 1 and at the non-inverting input of the comparator C 2 . As a result of the transmission of the sampling pulse ip by the transformer TF , a potential VR + v appears at the common connection point of the resistors R 5 and R 6 and thus at the non-inverting input of the comparator AC 1 . This comparator thus receives at its non-inverting input a signal with an amplitude that is greater than the amplitude of the signal that is present at the inverting input. This comparator has an open output. Similarly, the common connection point of the resistor R 4 and the inverting input of the comparator AC 2 receives a potential Vr - v (equal to -Vd). Since the size of this potential is smaller than that of the potential Vr at the non-inverting input of the comparator AC 2 , this comparator also does not provide an output signal (open output). The load resistor R 7 is therefore not switched through to the transformer TF . However, this is only the case if the current flowing via the line LT is zero or less than a predetermined value, which causes a potential difference at the connections of the capacitor C 1 which is greater than the voltage v. The load for the second winding of the transformer TF is determined in this case by the series connection of the diode D 1 and the resistors R 6 , R 5 and R 4 . The value of this load is approximately 10 kΩ. This resistance is translated by the transformer to the primary side, so that a current i 1 flows through the first winding . The evaluation voltage at the evaluation resistor R 8 then has the value Vm 1 .

If a current now flows via line LT in the direction from connection A to connection B and thus the potential at connection A is higher than the potential at connection B , the resistor connected to connection A via a resistor R 2 (100 kΩ) receives non-inverting input of the comparator AC 1 a signal that is greater than the one connected to the to the terminal B via a resistor R3 (100 ohms), inverting input of the comparator AC 1 occurs. The comparator is therefore kept in the aforementioned state and provides no signal

The comparator AC 2 receives a signal at its inverting input which is greater than the signal present at its non-inverting input. The comparator AC 2 is therefore triggered; it delivers a potential -Vd at its output, ie its output and thus the one connection of the load resistor R 7 are connected to the common connection point of the resistor R 4 and the second winding of the transformer TF . The load on the second winding is thus essentially determined by the load resistance R 7 . The total load is approximately 0.9 kΩ. This resistance is translated to the primary side of the transformer TF , so that a current i 2 flows through the first winding which is approximately ten times greater than the current i 1 . The evaluation voltage Vm at the evaluation resistor W 8 is therefore Vm 2 = 10 · Vml 1 .

It is clear from what has been described above that the detection threshold is determined in particular by the values of the resistors R 4 and R 5 . If a current flows via line LT in the direction from terminal B to terminal A and the potential at terminal B is higher than at terminal A , the comparator AC 2 receives a signal at its non-inverting input which is greater than that at its inverting Input occurring signal is. The comparator AC 2 is therefore triggered and no longer delivers a signal at its output. The comparator AC 1 receives a signal at its inverting input which is greater than the signal occurring at its non-inverting input. The comparator AC 1 is therefore triggered and outputs an output signal - Vd . Its output is connected to the terminal - Vd and thus to the common connection point of the resistor R 4 and the second winding of the transformer TF . As a result, the load resistor R 7 is switched through to the second winding. The total load on the transformer is again about 0.9 kΩ. As described previously, a current i 2 flows again through the first winding of the transformer TF , and the evaluation voltage at the evaluation resistor R 8 is again Vm 2 .

Therefore, if a current of any direction flows over the line LT , the sampling pulse ip transmitted via the transformer TF switches the load resistor R 7 on to the second winding, as a result of which a current flows in the first winding that is several times higher than in the case which no current flows over the line LT . The very easy evaluation of the current flowing through the first winding of the transformer TF therefore enables a line current to be determined.

The current detection circuit according to the figure has the advantage that the evaluation takes place completely free of line potential because only the second winding of the transformer TF is connected to the line LT . The current detection circuit is therefore protected against the overvoltages occurring on the line LT . Another advantage is that the measuring resistor R 1 inserted in the line can be negligibly small (3.9 ohms in the example), and in the limit case almost zero, provided that the offset voltages of the amplifier comparators can be extremely low. The connection of the current detection circuit to the line therefore does not involve any changes in the line characteristics. On the other hand, said predetermined value (threshold value) can be easily adjusted by carefully selecting the values of the resistors R 4 and R 5 . Through the use of the resistors R 2 and R 3 (each of about 100 kΩ) and the capacitor C 1 (for example 0.1 μF), insensitivity to interference voltages that occur on the line is achieved, and moreover the other, Components used in the current detection circuit protected.

Claims (8)

1. Circuit arrangement for determining a current flowing through a telecommunication line with a transformer with two windings, the first of which is connected to a scanning source and to a circuit for testing the current flowing through this winding and a coupling circuit between the second and the telecommunication line, characterized in that the coupling circuit has a first comparator ( AC 1 ) which is controlled by the telecommunication line current and which is loaded by a load ( R 7 ) fed via the transformer (TF) . 2. Circuit arrangement according to claim 1, characterized in that the comparator ( AC 1 ) is fed by scanning pulses (ip) which are transmitted via the second winding of the transmitter. 3. Circuit arrangement according to claim 2, characterized in that the second winding is loaded by means of the first comparator ( AC 1 ) with a load impedance ( R 7 ) when the comparator is controlled with such a current flowing in a first direction via the telecommunication line which exceeds a predetermined amplitude threshold. 4. Circuit arrangement according to claim 3, characterized in that the coupling circuit has a second comparator ( AC 2 ) which is controlled by the telecommunication line current and which switches through the load impedance ( R 7 ) to the second winding when the via the telecommunication line in a second Direction flowing current exceeds a predetermined amplitude threshold. 5. Circuit arrangement according to claim 4, characterized in that the second comparator (AC 2 ) is fed by scanning pulses (ip) which are transmitted via the second winding of the transformer. 6. Circuit arrangement according to claim 4, characterized in that the first comparator ( AC 1 ) with its first input (+) via a first resistor ( R 6 ) to the first terminal of the second winding and via a series connection of a second and third resistor ( R 5 , R 2 ) to one connection (A) , with its second input (-) via a fourth resistor ( R 3 ) to the other connection (B) of the line measuring resistor ( R 1 ) and with its output via a load resistor ( R 7 ) is connected to the first terminal of the second winding of the transformer (TF) . 7. Circuit arrangement according to claim 6, characterized in that the second comparator ( AC 2 ) with its first input (+) to the second input (-) of the first comparator ( AC 1 ), with its second input (-) to the second Connection of the second winding and its output is connected to the output of the first comparator ( AC 1 ). 8. Circuit arrangement according to claim 7, characterized in that a fifth resistor ( R 4 ) is arranged between the common connection point of the second and third resistor ( R 5 , R 2 ) and the second input (-) of the second comparator ( AC 2 ) . 9. Circuit arrangement according to claim 8, characterized in that the values of the third and fourth resistor (R 2 , R 3 ) are the same and in relation to the second and fifth resistor ( R 5 , R 4 ), which are also identical to one another, are high . 10. Circuit arrangement according to claim 9, characterized in that between the common connection point of the second, third and fifth resistor ( R 5 , R 2 , R 4 ) and the directly connected inputs of the first and second comparators, a capacitor ( C 1 ) is arranged is.