JPH0379899B2 - - Google Patents

Description

[Detailed Description of the Invention] [Technical Field of the Invention] The present invention relates to a system for constantly monitoring relay transmission lines of the same line, and in particular, it is possible to comprehensively monitor relay transmission lines, and also to monitor relay transmission lines for one line. The present invention relates to a constant monitoring method that can shorten the monitoring time of the entire relay transmission path.

[Conventional technology]

When constantly monitoring relay transmission lines and locating faults, generally the PCM signal output from the branch output end of each repeater is input to a monitoring device, and this monitoring device checks the regularity of the PCM signal. This method is adopted.

An example of this type of transmission path monitoring system is shown and explained in FIG. 1. FIG. 1 is a connection diagram illustrating the application of the present invention, and shows a terminal relay device, a repeater, a monitoring device, and the like in PCM relay transmission. This shows the connection of the comprehensive monitoring device.

In the figure, 1 is terminal relay device 2-1, 2-2
...2-n is a repeater installed in cascade connection to this terminal station repeater 1, and these repeaters 2-1 to 2
-n is configured to perform arithmetic and amplification to ensure transmission loss of the relay lines L ₁ , L _{2 .} . . _Lo, respectively, and further perform identification and re-pulsing. 3
-1, 3-2, 3-3...3-n are branch signal connection lines for connecting the PCM signals output from the branch output terminals of terminal station repeater 1 and repeaters 2-1, 2-2...2-n, respectively. BSL ₁ , BSL ₂ , BSL ₃ ...These are monitoring devices that receive input via BSL _o , and each has its own address. 4 is a general monitoring device, and this general monitoring device 4
are connected to each of the monitoring devices 3-1 to 3-n via an intervening pair 5.

In the transmission line monitoring system configured in this way, the PCM signal sent from the terminal relay device 1 is input to the repeater _2-1 through the relay line L1,
This repeater 2-1 performs equalization and amplification to ensure the transmission loss of the relay line _L1 , and also performs identification and amplification.
It performs re-pulsing and sends the output to the next stage repeater _2-2 via the relay line L2. Thereafter, similar operations are performed in sequence, and the repeater 2-n transmits the PCM signal to a repeater (not shown) connected further downstream. Then, the output signal is output from the branch output terminal of the terminal repeater 1 and each repeater 2-1 to 2-n.
As mentioned above, the PCM signals are sent to the monitoring devices 3-1 to 3 through the branch signal connection lines BSL ₁ to BSL _o , respectively.
−n respectively.

Further, a call signal is sent from the general monitoring device 4 to each of the monitoring devices 3-1 to 3-n through the intervening pair 5. Here, each of these monitoring devices 3-1 to 3-n
As mentioned above, each has a separate address,
If the call signal is for itself, an error pulse is sent back to the overall monitoring device 4. This general monitoring device 4 is connected to each monitoring device 3.
By repeating these operations sequentially for -1 to 3-n, the entire relay transmission path is monitored.

In this way, in the transmission path monitoring system shown in FIG.
1 to 3-n are connected and use a common intervening pair 5 as a monitoring line, so each monitoring device 3-1 to 3
-n operations are controlled on a time-sharing basis. Therefore, to monitor the output signal of a specific repeater, individual address signals assigned to each monitoring device are sent from the overall monitoring device 4 via the intervening pair 5, and the specific monitoring device is called. Any monitoring device sent back will return any error in the output signal of the repeater. Therefore, the comprehensive monitoring device 4 counts the error pulses and calculates the error rate.

However, in the transmission path monitoring system with such a configuration, each of the called repeaters 2-1 to 2-2
- Since the error pulse in the output signal of -n is simply sent back to the comprehensive monitoring device 4, if the number of repeaters to be monitored increases, the monitoring time of the entire relay transmission path will inevitably increase. It will increase in proportion to the number.

Furthermore, since all repeaters are not monitored at the same time, it is difficult to comprehensively judge the error state of the relay transmission line, which changes as a function of time. Therefore, means for monitoring the output signals of all repeaters at the same time and means for shortening the communication time between the comprehensive monitoring device 4 and the monitoring devices 3-1 to 3-n are required.

[Object and structure of the invention]

In view of the above points, the present invention has been made to solve such problems and eliminate such drawbacks, and its purpose is to provide a means for satisfying the above-mentioned needs with a simple configuration, that is, to provide a means for monitoring It is an object of the present invention to provide a constant monitoring system that can simultaneously monitor the output of each repeater installed on a target relay transmission path and shorten the communication time between intervening pairs.

In order to achieve such an object, the present invention provides that each of the plurality of monitoring devices includes an error detection circuit that receives an output signal output from a branch end of a repeater and detects an error state of a relay transmission line; An error counting/arithmetic circuit that inputs the error signal from the detection circuit, counts the error signal, and calculates the error rate; a memory that stores the error ratio signal from the error counting/arithmetic circuit; A communication control circuit that inputs the error information and controls the error detection circuit, error counting/arithmetic circuit, and memory, respectively, and a means for transmitting only the error rate information to the comprehensive monitoring device by means of an intervening pair. A large number of installed repeaters can be monitored at the same time, and the monitoring results can be stored in a memory housed within the monitoring device.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

FIG. 2 is a block diagram showing an embodiment of the constant monitoring system according to the present invention, and only the parts necessary for explanation are shown.

The parts surrounded by chain lines in FIG. 2 correspond to the monitoring device shown in FIG. 1, and the same reference numerals indicate corresponding parts. Then, this monitoring device 11 is connected to 3-- in FIG.
The output signal output from the branch output end of the repeater shown in Fig. 1, that is, the PCM signal, is input to the branch signal connection line BSL shown in Fig. 2. is configured to be The intervening pair 5 is connected to the comprehensive monitoring device 4 shown in FIG. 1 and other monitoring devices.

11-1 is an error detection circuit that receives the PCM signal from the branch signal connection line BSL and detects an error state of the relay transmission line; 11-2 is this error detection circuit 11-
11-3 is an error counting/arithmetic circuit which inputs the error pulse EP from 1 and counts the error pulse EP to calculate the error rate; 11-3 is this error counting/arithmetic circuit 11
- a memory for storing the error ratio signal ERS from 2;
11-4 inputs the error ratio signal M・ERS stored in this memory 11-3, and controls the error detection circuit 11-1, error counting/arithmetic circuit 11-2, and memory 11-3 by means of a control signal CS. This communication control circuit 11-4 controls each communication control circuit.
is connected to the overall monitoring device 4 shown in FIG. 1 via the intervening pair 5.
It is connected to the.

Then, by setting/resetting an error rate counter (not shown) of each repeater using a trigger signal from the terminal station, all repeaters are configured to be monitored at the same time. ing.

Next, the operation of the embodiment shown in FIG. 2 will be explained with reference to FIG.

First, a command signal is sent from the comprehensive monitoring device 4 shown in FIG. 1 to all the monitoring devices through the intervening pair 5 to start their operations. All the monitoring devices receiving this command are connected to the communication control circuit 11- shown in FIG.
This command is decoded in step 4, and the error detection circuit 11-
1. Error counting/arithmetic circuit 11-2 and memory 1
A control signal CS is generated to operate 1-3.

At this time, the error detection circuit 11-1 performs error detection for a certain period of time on the PCM signal output from the branch output terminal of the repeater shown in FIG. 1, which is the input signal of the error detection circuit 11-1. After counting is performed by the error counting/arithmetic circuit 11-2, only the error rate is stored in the memory 11-3.

Note that in order to convert the counting result obtained by the error counting/arithmetic circuit 11-2 into an error rate signal, the control signal CS from the communication control circuit 11-4 is stopped after a certain period of time has elapsed.

Thereafter, the general monitoring device 4 (see FIG. 1) calls each monitoring device to collect error rate information. That is, each monitoring device has a different individual address, so that the general monitoring device 4 shown in FIG.
1 to 3-n and collect the error rate information stored in the memory 11-3. Then, through this procedure, the comprehensive monitoring device 4 sequentially collects the error rate information stored in the memories of all the monitoring devices.

Further, the comprehensive monitoring device 4 collects all of the error rate information and repeats a series of operations to constantly monitor the relay transmission path and comprehensively locate the fault location.

In the above embodiments, the common intervening pair as the monitoring line was explained as an example of a two-wire type, but the present invention is not limited to this.
It is clear that the same constant monitoring can be performed even with a wire system. Furthermore, it is clear that the same constant monitoring can be performed by increasing the number of relay transmission lines to be monitored, that is, by increasing the number of lines or by increasing the number of associated repeaters.

For example, consider here the n=10 error detection time in FIG. 1 as 5 seconds. Therefore, in the conventional system, since the error detection time for one repeater is 5 seconds, the error detection time is 5×10=50 seconds. In contrast, in the present invention, since the error rate counters of each repeater are set/reset at the same time, the error rates of 10 repeaters can be detected in 5 seconds. Since the communication time α seconds between the general monitoring device and the monitoring device is considered to be much smaller than 5 seconds, simply consider,
When n=10, it is possible to shorten the time by nearly 1/10 compared to the conventional method.

In this way, since the output signals of all repeaters can be monitored at the same time, it is possible to comprehensively monitor the relay transmission path, and since all monitoring devices can calculate and store errors, It is possible to shorten the monitoring time of the entire relay transmission path for the line.

〔Effect of the invention〕

As is clear from the above description, according to the present invention, the means for monitoring the output signals of all repeaters at the same time and the calculation and storage of errors in all monitoring devices are performed without using complicated means. With a simple configuration equipped with means, it is possible to comprehensively monitor the relay transmission line, and the time required to monitor the entire relay transmission line for one line is significantly reduced compared to conventional services. Therefore, the practical effect is extremely large.

[Brief explanation of drawings]

FIG. 1 is a connection diagram illustrating the application of the present invention;
FIG. 2 is a block diagram showing one embodiment of the present invention. 1... End station relay device, 2-1 to 2-n... Repeater, 3-1 to 3-n... Monitoring device, 4... Overall monitoring device, 5... Intervening pair, 11... Monitoring device , 11
-1...Error detection circuit, 11-2...Error counting/
Arithmetic circuit, 11-3...Memory, 11-4...Communication control circuit.

Claims (1)

[Claims] 1. A plurality of repeaters installed in cascade connection on the relay transmission path of the same line, a plurality of monitoring devices each receiving output signals output from the branch output terminals of the plurality of repeaters, and In a transmission path monitoring method that consists of a monitoring device and a general monitoring device connected by an intervening pair, and in which the general monitoring device calls each monitoring device through the intervening pair to monitor the transmission path, each of the plurality of monitoring devices , an error detection circuit that receives the output signal output from the branch output end of the repeater and detects an error state of the relay transmission line; and an error detection circuit that receives the error signal from the error detection circuit and counts the error signal and detects an error. an error counting/arithmetic circuit for calculating the error ratio; a memory for storing the error ratio signal from the error counting/arithmetic circuit; and an error detecting circuit and the error counting/arithmetic circuit using the error rate information stored in the memory as input. A communication control circuit that controls each circuit and memory, and a means for transmitting only error rate information to the general monitoring device by the intervening pair, and monitors a large number of repeaters installed on the relay transmission path at the same time. A constant monitoring system characterized in that the monitoring results can be stored in a memory housed in the monitoring device.