DE2757021A1 - Fault locating system for digital repeaters - has test loop contg. differential amplifier switched in and out in opposite phase to line amplifiers - Google Patents

Abstract

The fault-locating system for repeater amplifiers in a digital communications network passes the regenerated signals directly the transmit amplifier. The amplifiers for the a and b wires each consist of a differential amplifier switched in and out by a switching signal. A third diff. amp. is connected by its input in parallel with the first amplifier and lies in the test loop. The third amp. is switched in adn out in opposite phase to the other two amplifiers.

Description

Circuit arrangement for determining the fault location in intermediate

amplifier positions The invention relates to a circuit arrangement for fault location in repeater stations of communication links, especially of digital communication links in which a detector evaluates a switching signal sent by a terminal through which the A and B transmission line switched off and a test loop for transmitting a test signal is closed.

Such a circuit arrangement is described in DT-OS 20 14 645. In this case, to test the function of the pulse regenerators first with a The individual lines and the test loops are separated by a low-frequency switching signal closed. After a test signal has passed through the first repeater, its line connection is closed again and the loop is opened. In this way, all repeater stations are checked one after the other. As a test signal a signal is preferably used that has the same structure as a useful signal. In digital transmission systems, the test signal is accordingly a pulse train.

It can be used to calculate the pulse error rate of a pulse regenerator measure up. Their increase can indicate that the pulse regenerator is beginning to malfunction of the repeater in question are closed.

For connecting and disconnecting the transmission lines and for switching the test loop are provided in the DT-OS 20 14 645 logic gates before the line amplifiers.

Since the switching signal and the information signal are input variables of the same Gates are, the operating speed (rise times, delay times) the gate is adapted to the fastest signal, in this case the information signal be.

This causes a high power loss. With ternary line signals the cost of gates is even twice as large, since two binary bit streams are switched Need to become. Due to different large delay and rise times of the front and trailing edge of a pulse, as occurs in integrated logic circuits, the pulse widths can be falsified. In addition, the two can be regenerated binary bit streams with ternary line signals, especially with high bit repetition rates, between regenerator and line amplifier with the interconnection of gates have different terms.

The object of the invention is to provide a circuit arrangement of the initially mentioned specified type, in which the regenerated signals are sent directly to the transmitter amplifier are supplied and which contains a switching device, its operating speed is matched to the relatively slow switching signal.

In addition, the circuit arrangement should have a current consumption that is as constant as possible have in all operating cases.

According to the invention, this object is achieved in that the line amplifiers the A and B transmission lines from first and second to one Control input switchable differential amplifier are formed by the switching signal are switched on or off in the same direction and that the first differential amplifier on the same third differential amplifier at the input, switchable at a control input is connected in parallel, which is in the test loop and in opposite directions from the switching signal to the other two differential amplifiers is switched off or on.

This ensures that the intermediate amplifier is on the A side either the first or the third differential amplifier is switched on, depending on whether a useful signal is transmitted or a test signal is looped back. Both signals run through essentially symmetrically constructed circuit paths. In one case the useful signal at the output of the intermediate amplifier point on the A side is sent to the A transmission line carry over. Otherwise the test signal is at the output the 8-side of the repeater station on the B-transmission line. Switching from one differential amplifier to the other as a result of the switching signal thus does not result in any significant change in the current consumption.

In a preferred embodiment of the invention, the switching signal switches the differential amplifiers, in particular the first and third differential amplifiers, at their control inputs via a control circuit, the two parallel identically constructed Has switching branches, with both switching branches connected to a common current source and, depending on the switching status, only one of the two switching branches carries current.

In transmission systems, especially those with a series supply of the Repeater stations, it is often necessary to have the A and 8 sides in terms of potential to decouple. In these cases a transformer is arranged in the test loop. In an embodiment of the invention, it is then advantageous to use the switching signal via a To route opto-coupler to the control input of the second differential amplifier. In order to is a simple way of transferring the voltage generated by a DC voltage Switching signal given from the A to the B side.

Further advantageous refinements of the invention emerge from the following description of exemplary embodiments and the subclaims individually or in combination. In the drawing show: Figs. 1 and 2 one Repeater of a digital transmission system without galvanic decoupling the A and B sides, FIG. 1 showing the A side and FIG. 2 showing the 8 side; Fig. 3 and 4 a repeater point of a digital transmission system with galvanic Decoupling of the A and B sides, with FIG. 3 the A side and FIG. 4 the B side shows; 5 shows a further embodiment of the B-side with galvanic decoupling the switching signal; 6 and 7 a further embodiment with galvanic Decoupling of the A and B sides for ternary signals, FIG. 6 showing the A side and Fig. 7 shows the 8-side.

A pulse regenerator 1 is located in the A transmission line (see Fig. 1). Signal inputs are located in parallel at signal outputs 2 and 3 of regenerator 1 two switchable differential amplifiers 4 and 5.

A detector 6 is also provided in the intermediate amplifier. Such a detector can, for example, as described in DT-OS 20 14 645 be constructed. This essentially works with two detection circuits 7 and 8, each to a low-frequency switching signal of the not shown Address the end of the transmission line and control a flip-flop 9. At output terminals 10 and 11 is the flip-flop 9 with a control circuit 12 for the differential amplifier 4 and 5 connected.

At the output of the differential amplifier 4 is located in front of the transmission line A is a transformer 13. The output of the differential amplifier 5 is via terminals 14 and 15 are connected to a transformer 16 which is in the line (see Fig. 2).

On the side of the repeater point in Fig. 1 is a regenerator 17 is provided, at its outputs 18 and 19 a further switchable differential amplifier 20 lies. This is also on the output side at the transformer 16. A control circuit 21 for the differential amplifier 20 is connected on the input side to terminals 10 and 11 of the Flip-flops 9 in Fig. 1 connected.

The differential amplifiers 4, 5 and 20 in FIGS. 1 and 2 are symmetrical and set up the same way. Each differential amplifier has three transistors T1, T2, T3 or T4, T5, T6 or T7, TS, T9. The transistors T3, T6 and T9 with their collectors at the coupled emitters of the transistors T1, T2 and T4, T5 or T7, T8. The bases of the transistors T3, T6, T9 form the control input of the respective differential amplifier and are connected to the control circuit 12 and 21, respectively. The emitters of the transistors T3, T6 and T9 are connected via resistors R1, R2 and

R3 at the negative pole of the supply voltage UA or UB. The signal inputs the differential amplifiers 4, 5 and 20 are connected to the bases of the transistors T1, T2 and T4, TS or T7, T8 formed.

The collectors of the transistors mentioned form the outputs of the Differential amplifier.

The control circuit 12 in FIG. 1 consists of two parallel switching branches constructed, the one switching branch consisting of a transistor no, a transistor T12 and a resistor R4 and the other circuit branch consists of a transistor Tll, a transistor n 3 and a resistor R5. The resistors R4 and R5 are connected to the negative pole of the supply voltage UA.

The base of the transistor Tll is at the output 11 of the flip-flop 9. The collector base lines of transistors T12 and T13 are short-circuited. The base of the transistor T12 is connected to the base of the transistor T3 and the base of the transistor T13 is connected to the base of the transistor T6.

The control circuit 21 in Fig. 2 is made up of transistors T14, T15, T16 and a resistor R6 constructed similarly to the control circuit 12. Since the control circuit 21 only has to control the differential amplifier 20, the transistor is superfluous T13 corresponding transistor and a resistor corresponding to resistor R5 of Fig. 1.

The control circuits 12 and 21 are temperature-compensated Power source 22 or 23 fed. Both power sources have the same structure. You insist from a transistor T17 or T18, the emitter of which is connected via a resistor R7 or R8 is connected to the positive pole of the supply voltage UA or U8. The collector of the The transistor T17 or T18 is connected to the coupled emitters of the transistors T10, Tll or T14, T15 connected. The base of the transistor T17 or T16 is connected to the Base of another transistor T20 or T19 with a short-circuited base-collector path. The emitter-collector path of the transistors T20 resp.

T19 is in series with resistors R9, R10 or Rll, R12 between the positive and negative poles of the supply voltage.

In normal operation, the output 10 of the flip-flop 9 is low (low) and at the output 11 of the flip-flop 9 H-potential (high).

The transistors no and n4 conduct. The transistors Tll and T15 are locked. As a result, transistors T3 and T9 are conductive and transistor T6 is locked. The differential amplifiers 4 and 20 are thus activated. The differential amplifier 5 is blocked.

In this case, a useful signal of the A line is transmitted via the differential amplifier 4 and the transmitter 13 forwarded on the A line. The same applies to the 8 line. Regardless of whether the useful signal to be transmitted is H or L, one of the two transistors T1 or T2 is always conductive. The same is applicable when transmitting a useful signal on the 8-side for transistors T7 and TS. The power consumption of the differential amplifier is derived from the bit pattern of the useful signal 4 and 20 thus independent.

In the test mode, a sent by the terminal, in the Detection circuit 7 of the detector 6 evaluated switching signal the flip-flop 9 implemented so that the output 10 is L potential and the output 11 is H potential. The transistors T10 and Tll or T14 and T15 switch accordingly. The transistors T3 and T9 are now blocked. The transistor T6 is conductive. Via the differential amplifier 4 and 20, no signal can be transmitted in this case. From the testing terminal a test signal is sent out, which is, for example, a pseudo-random signal. This gets through the regenerator 1 to the now activated differential amplifier 5 to the transformer 16 via the terminals 14 and 15 in the test loop the B-side and from there back to the checking end office. There it can be found in terms of to evaluate the pulse error rate of regenerator 1.

The fact that in normal operation two differential amplifiers, namely 4 and 20 and in the test mode only one differential amplifier, namely 5 switched through means a different current consumption in both operating cases. In In practice, this can be avoided by using the supply voltage on the A side is decoupled from the side. In this case it is then on the A side on the the regenerator 1 to be tested is located, the power consumption is the same in both cases. With reference to Fig. 5, a circuit is described in which two on the B-side alternately activated regenerators are used. This can also be done with the Realize the circuit according to FIG.

In transmission systems in which the supply voltage is the A and B-sides of the repeater stations are supplied in series, the voltage levels the A and 8 sides are different. It is therefore necessary to do that from the A-side to decouple the signals to be transmitted on the 8-side in terms of potential. In Fig. 3 is a corresponding embodiment for the A-side and in Fig. 4 the corresponding 8-page shown. Corresponding to the circuit parts already described Circuit parts are provided with the same reference numerals. The same applies to them above Said.

Between the collectors T4 and T5 of the differential amplifier 5 in Fig. 3 is the primary side of a test signal transmitter 24.

The collector of the transistor T5 is also connected to a light-emitting one Diode 25 on the positive supply voltage UA on the A side. Lies on the secondary side the test signal transmitter 24 on an additional winding 26 of the transmitter 16 the B-side.

The connection poles of the winding 26 with the transformer 24 are with 27 and 26. The light emitting diode 25 radiates one in the control circuit 21 of the 8-side arranged phototransistor 29. The phototransistor 29 is located with a voltage divider made up of resistors R13, R14 at the base of transistor T14. A reference voltage is applied to the base of the transistor T15. Flows in normal operation no current through the differential amplifier 5, so that the photodiode 25 also does not shines. In the test mode, the photodiode lights up, so that the phototransistor 29 switches through. As a result, the differential amplifier 20 is via the control circuit 21 blocked. A test signal can now be sent from the differential amplifier 5 via the test signal transmitter 24 and winding 26 can be transferred to the B line. With the help of the opto-coupler 25, 29 it is possible in a simple manner to indicate the respective switching state DC voltage signal from the A-side to the 8-side transferred to. The current flow through the diode 25 does not lead to an increased current consumption of the Differential amplifier 5, since the transistor T6 of the differential amplifier 5 acts as a constant current source works.

In Fig. 5, a further embodiment is shown for the side. In this case too, as in FIGS. 3 and 4, there is a potential decoupling both sides worked.

In addition, a further differential amplifier 30 is provided. This is just like the other differential amplifiers with transistors T21, T22 and T23 and a resistor R15. The is at its input terminals 27 and 28 Secondary side of the test pulse transmitter 24. The control circuit 21 is similar to the control circuit 12 according to FIG. 1. However, like that according to FIG. 4, it is controlled by the phototransistor 29. The output of the differential amplifier 30 is parallel to that of the differential amplifier 20 on the primary winding of the transformer 16.

In normal operation, the differential amplifier 20 is activated and the Differential amplifier 30 is blocked. If a test signal is to be transmitted, then the differential amplifier 20 is blocked and the differential amplifier 30 is activated, so that a test signal arriving via terminals 27 and 28 is sent to the 8 line is looped back.

In digital transmission systems, ternary signals can be used on the Transmission path to be worked. In this case, the differential amplifiers three inputs and outputs.

Additional transistors T1 ', T4', T7 'provided. The transformers 13 ', 16', 24 'are correspondingly in the figures 6 and 7 to switch. The formation of the ternary transmission signals The two binary regenerator output signals are used as a transmission amplifier serving differential amplifiers.

Further exemplary embodiments of the invention result from connection individual circuit measures of the circuits described. The differential amplifier 5 can also be arranged in the B-side of the repeater station. He is then connected to the supply voltage of the B-side.

The differential amplifiers described are themselves the transmission amplifiers the transmission line. These are switched via their power sources, whereby the Control input of the power sources practically represents an enable input. Through this that the inputs of the differential amplifier directly to the output of the regenerator are connected, pulse distortion is largely avoided. That of the error evaluation The test signal used runs over essentially the same stages as that Useful signal. A separate amplifier, also from a differential amplifier, is used for the test signal educated transmission amplifier provided. The power loss required for switching is relatively low. According to the operating conditions of the regenerator and the Power supply to the repeater can be one of the occurring Achieve practically independent power consumption in operating cases.

Claims (7)

Claims 1. Circuit arrangement for fault location in intermediate amplifier stations of message transmission routes, in particular of digital message transmission routes, in which a detector evaluates a switching signal sent by a terminal, by which the A and B transmission lines are switched off and a test loop for the transmission of a test signal is closed, characterized. that the line amplifiers of the A and S transmission lines from a first and a second differential amplifier (4, 20) which can be switched at a control input are that are switched on or off in the same direction by the switching signal and that the first Differential amplifier (4) an identical third, switchable at a control input Differential amplifier (5) is connected in parallel at the input that is in the test loop (14, 15) and from the switching signal in opposite directions to the other two differential amplifiers (4, 20) is switched off or on. 2. Circuit arrangement according to claim 1, characterized in that the switching signal the differential amplifier (4, 5, 20, 30), in particular the first and third differential amplifier [4, 5), at their control inputs via a control circuit (12, 21) switches the two parallel, identically constructed switching branches (T10, n2, R4; Part, n3, R5), with both switching branches connected to a common current source (22, 23) and, depending on the switching state, only one of the two switching branches current leads. 3. Circuit arrangement according to claim 1 or 2, wherein the potentials the A and 8 sides are decoupled and a transformer is arranged in the test loop is, characterized in that the switching signal via an optocoupler (25, 29) and optionally via the control circuit (21) to the control input of the second Differential amplifier (20) is passed. 4. Circuit arrangement according to claim 3, characterized in that a light-emitting diode (25) of the optocoupler (25, 29) in series with the third Differential amplifier (5) is located. 5. Circuit arrangement according to one of the preceding claims, characterized characterized in that the differential amplifier for binary signals consists of two transistors (Tl, T2; T4, T5; T7, T8; T21, T22) are constructed with coupled emitters and that a transistor (T3, T6, T9, T23) connected as a current source is connected to the emitters, the basis of which forms the control input of the differential amplifier. 6. Circuit arrangement according to one of the preceding claims, characterized characterized in that a fourth, switchable differential amplifier (30) with his Output is parallel to the second differential amplifier (20) and its signal input (27, 28) is connected to the signal output of the third differential amplifier (5). 7. Circuit arrangement according to one of the preceding claims, characterized characterized in that the differential amplifier with a further for ternary signals Transistor (T1 ', T4', T7) work.