DE2004810C3 - Method and arrangement for determining errors in the intermediate points provided with regenerators of a transmission system operating with pulse code modulation - Google Patents

Description

The invention relates to a method and an arrangement for determining errors in the intermediate points provided with regenerators of a transmission system operating with pulse code modulation and having a plurality of transmission channels from a checking end office using bandpass filters in the individual intermediate points.

A fault location method of this type is already known from German Auslegeschrift 1 298 553, in which various circuit arrangements are provided in each intermediate point for carrying out the method, which circuit arrangements respond to individual address pulses.

The object underlying the invention is is to specify a fault location method that manages with the same circuit arrangement in each intermediate point.

Based on a method of the type described in the introduction, this object is achieved according to the invention in that a first pulse pattern is sent out as a start pulse by the checking end office, that at the end of the start pulse in all intermediate points on the one hand a loop closure is established on the output side and on the other hand the flow of messages on the through lines behind the Loop closure is interrupted, that a second pulse pattern is sent as the first test pulse from the checking end office through the loop and evaluated, that a third pulse pattern is sent out as the first setting pulse by the checking end office, that at the end of the first setting pulse the loop closure and the interruptions in the first intermediate point that a fourth pulse pattern is transmitted and evaluated as a second test pulse by the testing end office through the loop via the second intermediate point and that further alternating setting pulses of the same pulse pattern and test pulses a be sent until all intermediate points have been checked.

For the practical implementation of the method according to the invention it is advantageous if the pulse pattern of the start pulse contains a modulated first low-frequency voltage and if the pulse patterns of all setting pulses contain a modulated second low-frequency voltage.

It is advantageous if the pulse pattern of the start pulse is demodulated in each intermediate point and fed to a first bandpass filter that is matched to the frequency of the first low frequency voltage, the output voltage of which causes the loop closure and the interruptions, and if the pulse pattern of the setting pulses in the last of the respective with the checking Intermediate points connected to the end office are demodulated and fed to a second band-pass filter which is matched to the second low-frequency voltage and whose output voltage cancels the loop closure and the interruptions in the intermediate point which is still connected farthest away from the checking end office.

Another advantageous procedure is that the same pulse pattern is used for the start pulse and the setting pulses, that the output voltage of a bandpass filter resulting from the start pulse and the setting pulses is fed to a switching device at each intermediate point, which controls both the loop closure and the interruptions as well as their cancellation causes.

However, it is also possible to use any pulse pattern for the start pulse and the setting pulses, and when these are recognized, the loop closures and interruptions are actuated in the intermediate points.

The method according to the invention can be used with advantage from both end offices, which requires a duplication of the necessary circuit parts.

To carry out the procedure with two band filters in each intermediate point, an arrangement is advantageous which is characterized in that in the intermediate point at the output of the regenerator a demodulation circuit and at its output the first bandpass filter with a downstream first delay and switching device and the second bandpass filter with switched second delay and switching device is connected and that the first switching device causes the loop closure and the interruptions and the second switching device cancels the loop closure and the interruptions. To carry out the method variant with a bandpass filter in each intermediate point, an arrangement is advantageous which is characterized in that a demodulation circuit is connected in the intermediate point at the output of the regenerator and the bandpass filter with a downstream delay device and switching device is connected to its output, and the switching device is connected to one output which causes the loop closure and the interruptions, and at the other output of which the switching device which cancels the loop closure and the interruptions is connected.

For this arrangement it is advantageous if a switching device is provided with three switching positions, in the first of which all loop closings and interruptions are canceled, the second of which causes all loop closings and interruptions through the start pulse, the third of which causes the loop closings and interruptions gradually from the intermediate point through a setting pulse Intermediate point cancels again and the first is reached again by reversing the polarity of the supply voltage.

The invention is explained in more detail below on the basis of exemplary embodiments.

1 a and 1 b show an embodiment of a PCM message transmission system with two terminals 1 and 1 'and a transmission link 6, 7 connecting them with intermediate points 8, 8', 8 ". Each intermediate point 8, 8 ', 8" contains in the course of the through line 6 a regenerator 9, 9 'or 9 "and an interruption a 3, a 3' or a 3". In the course of the through line 7 for the opposite direction, each intermediate point 8, 8 ', 8 "contains a regenerator 13, 13' or 13" and an interruption a 2, a 2 'or a 2 ". Each intermediate point 8, 8' or 8" contains a loop closure a 1, a 1 'or a 1 ", which, viewed from the terminal 1, which acts as the checking terminal, is arranged in each intermediate point 8, 8' or 8" on the output side before the interruptions.

2 shows a pulse program used to locate faults. X is the start pulse, y 1 and y 2 are test pulses, and z 1 and z 2 are setting pulses. This pulse sequence is transmitted from the checking end office 1 onto the line 6.

The start pulse x is received in the arrangement according to FIG. 1a in all intermediate points 8, 8 ', 8 ". After termination of this start pulse x, the loop closures a 1, a 1' and a 1 "closed and all interruptions a 2, a 3; a 2 ', a 3'; a 2", a 3 "open. The test pulse y 1 emitted by the testing end office 1 runs over the line 6, the regenerator 9, The loop closure a 1, the regenerator 13 and the line 7 are returned to the checking terminal office 1 and evaluated there. The setting pulse z 1 is then transmitted via the line 6 to the intermediate point 8. Because of the interruptions a 2 and a 3, it cannot continue the intermediate points 8 'and 8 "arrive. At the time of the termination of the

Control pulse z 1, the loop closure a 1 is opened, and the interruptions a 2 and a 3 are canceled. The subsequently transmitted test pulse y 2 flows via the line 6, the regenerator 9, the canceled interruption a 3, the regenerator 9 ', the loop closure a 1', the regenerator 13 ', the canceled interruption a 2, the regenerator 13 and the line 7 back to the testing terminal 1 and is evaluated. This case is shown in Fig. 1b. The second setting pulse z 2 now effects the switchover in the intermediate point 8 '. A test pulse y 3, which is no longer shown in FIG. 2, causes the intermediate point 8 ″ to be tested, and a third setting pulse z 3, no longer shown in FIG.

In FIG. 3, the circuit parts required to implement the method according to the invention are shown on the basis of an exemplary embodiment in the testing terminal 1 and the intermediate point 8. The testing terminal 1 contains a pulse comparison device 4 and a display device 5. In addition to the circuit elements already shown in FIG. 1a, the intermediate point 8 contains a demodulator circuit 10, a bandpass filter 11, a bandpass filter 11 ', a delay device 12 and a delay device 12', a switching device A and a switching device B. The switching device A triggers the loop closure a 1 and the interruptions a 2 and a 3. The switching device B actuates a switch b which switches off the switching device A. The switching devices A and B can be implemented by relays or electronic circuits. The checking end office 1 and the intermediate point 8 are connected to one another by lines 6 and 7.

The mode of operation of the arrangement according to FIG. 3 is as follows: A start pulse x is transmitted from the checking end office 1 to the intermediate point 8 via the line 6. This start pulse has a pulse pattern which contains a modulated first low-frequency voltage f 1. The start pulse x is demodulated in the demodulator circuit 10, so that the first low-frequency voltage with the frequency f 1 occurs at its output. The band-pass filter 11 is permeable to this frequency f 1, so that it also appears at the output of the band-pass filter 11. The delay circuit 12 passes on the first low-frequency voltage after the start of the pulse x to the relay A, which picks up and closes the working contact a 1 forming the loop and opens the break contacts a 2 and a 3 representing the interruptions.

A test pulse y 1 with any pulse pattern is now transmitted from the checking end office 1, which returns via the line 6, the regenerator 9, the contact a 1, the regenerator 13 and the line 7 to the checking end office and there to the pulse comparison device 4 and the display device 5 is fed. In the pulse comparison device 4, differences between the transmitted test pulse y 1 and the returning test pulse are evaluated.

After completion of this test step, the testing end office transmits a setting pulse z 1 via line 6 to intermediate point 8, the pulse pattern of which contains a modulated second low-frequency voltage of a different frequency f 2. The setting pulse z 1 is demodulated in the demodulator circuit 10, so that the second low-frequency voltage occurs at the output of this circuit. The band-pass filter 11 'is permeable to this frequency f 2. The delay circuit 12 'sends the low-frequency voltage to the relay b after the setting pulse z 1 has ended. This attracts and opens the normally closed contact b, which interrupts the power supply of the relay A, whereby the normally open contact a 1 opens again and the normally closed contacts a 2 and a 3 close again.

Fig. 4 shows an embodiment of the terminal 1 and an intermediate point 8 a. Compared to the arrangement according to FIG. 3, the arrangement according to FIG. 4 differs only in the intermediate point.

The intermediate point 8a is designed to receive a pulse program according to FIG. 2, in which the pulse pattern of the start pulse x corresponds to the pulse patterns of the setting pulses z 1 and z 2.

The demodulation circuit 10 is followed by a single band-pass filter 11 and this is followed by a single delay circuit 12. This is possible because the uniform pulse pattern of the start pulse and the setting pulses only contains a low-frequency voltage. After each termination of the start pulse or one of the setting pulses, an input voltage is applied to a switching device 14. The switching device 14 firstly has a normal position during which neither the relay A nor the relay B contain a current and the normally open contact a 1 is open and the normally closed contacts a 2 and a 3 are closed. A first voltage resulting from the start pulse x at the input of the switching device 14 sets its second position, during which the relay A draws current, closes its contact a 1 and opens its contacts a 2 and a 3. When a second voltage resulting from the setting pulse z 1 occurs at the input of the switching device 14, its third position is reached, through which the relay B receives current, picks up and opens the normally closed contact b, so that the relay A drops out. The occurrence of further voltages resulting from further test pulses z 2 etc. at the input of the switching device 14 does not change its position. The transition from the third to the first position takes place after the end of the test program by reversing the polarity of the supply voltage.

The switching device 14 can be implemented, for example, with two flip-flops or with a stepping mechanism.

The fault location method according to the invention can advantageously also be used in those intermediate regenerators whose properties are completely independent of direction. In this case, the devices for forming loops are to be provided on both sides of the intermediate regenerators 9, 13. The fault location can then be carried out from both terminals 1, 1 '. A command from one side only influences the behavior at the remote output of the intermediate amplifier. Nevertheless, in such a case an error could occur if a start or setting pulse is transmitted from both sides at the same time. A self-locking that occurs as a result can be remedied by brief DC interruptions.

Claims (10)

1. A method for determining errors in the intermediate points provided with regenerators of a transmission system operating with pulse code modulation with several transmission channels from a testing end office using bandpass filters in the individual intermediate points, characterized in that a first pulse pattern as a start pulse (x) from the testing end office (1) it is transmitted that at the end of the start pulse (x) in all intermediate points (8, 8 ', 8 ") on the output side, on the one hand, a loop closure (a1, a1', a1") is established and, on the other hand, the message flow on the through lines (6, 7) after the loop closure (a 2, a 3; a 2 ', a 3'; a 2 ", a 3") is interrupted that a second pulse pattern as the first test pulse (y 1) from the testing end office (1) through the Loop (a 1) is sent and evaluated that a third pulse pattern is sent out as the first setting pulse (z 1) by the checking end office (1), that at the end of the first setting pulse (z 1) the loop closure (a 1) and the interruptions (a 2, a 3) in the first intermediate point (8) are canceled, that a fourth pulse pattern as a second test pulse (y 2) from the testing end office (1) through the loop (a 1 ') via the second Intermediate point (8 ') is transmitted and evaluated and that further alternating setting pulses (z 2, z 3) of the same pulse pattern and test pulses (y 2, y 3) are transmitted until all intermediate points (8', 8 ") are checked. 2. The method according to claim 1, characterized in that the first pulse pattern of the start pulse (x) contains a modulated first low-frequency voltage of a first frequency (f 1). 3. The method according to claim 1, characterized in that the pulse pattern of all setting pulses (z 1, z 2) contain a modulated second low-frequency voltage of a second frequency (f 2). 4. The method according to claim 2, characterized in that the pulse pattern of the start pulse (x) is demodulated in each intermediate point (8, 8 ', 8 ") and fed to a first bandpass filter (11) tuned to the first frequency (f 1), whose output voltage causes the loop closure (a 1) and the interruptions (a 2, a 3). 5. The method according to claim 3, characterized in that the pulse pattern of the setting pulses (z 1, z 2) in the intermediate points (8, 8 ', 8 ") connected to the checking end office (1) are demodulated and one on the second frequency matched second bandpass filter (11 ') are supplied, the output voltage of which the loop closure (a 1, a 1', a 1 ") and the interruptions (a 2, a 2 ', a 2", a 3, a 3', a 3 ") in the intermediate point furthest away from the checking end office (1) and still connected to it. 6. The method according to claim 1, characterized in that the same pulse pattern (x = z 1 = z 2) is used for the start pulse and the setting pulses that the output voltage of a bandpass filter (11) resulting from the start pulse and the setting pulses in each intermediate point ( 8, 8 ', 8 ") is fed to a switching device (14) which controls both the loop closure (a 1, a 1', a 1") and the interruptions (a 2, a 3; a 2 ', a 3'; a 2 ", a 3") as well as their cancellation. 7. The method according to any one of claims 1 to 6, characterized by its implementation from both end offices (1, 1 '). 8. Arrangement for performing the method according to claims 4 and 5 or 7, characterized in that in the intermediate point (8) at the output of the regenerator (9) a demodulation circuit (10) and at its output the first bandpass filter (11) with a downstream first delay (12) and switching device (A) and the second bandpass filter (11 ') with a downstream second delay (12') and switching device (B) is connected and that the first switching device (A) closes the loop (a 1) and causes the interruptions (a 2, a 3) and the second switching device (B, b) cancels the loop closure (a 1) and the interruptions (a 2, a 3). 9. Arrangement for performing the method according to claim 6 or 7, characterized in that in the intermediate point (8) at the output of the regenerator (9) a demodulation circuit (10) and at its output the bandpass filter (11) with a downstream delay device (12) and switching device (14) is connected, at one output of which the switching device (A), which causes the loop closure (a 1) and the interruptions (a 2, a 3), and at the other output of which the switching device (B), which causes the Loop closure (a 1) and the interruptions (a 2, a 3) cancels, is switched on. 10. The arrangement according to claim 9, characterized in that a switching device (14) is provided with three switching positions, in the first of which all loop closures (a 1, a 1 ', a 1 ") and interruptions (a 2, a 3; a 2 ', a 3'; a 2 ", a 3"), the second of which causes all loop closures and interruptions by the start pulse (x), the third of which causes the loop closings and interruptions step by step from the intermediate point by a setting pulse (z 1, z 2) to the intermediate point and the first is reached again by reversing the polarity of the supply voltage.