JPS6330042A - Information transmitter - Google Patents

Abstract

PURPOSE:To quickly obtain the disconnection information of an optical fiber transmission line by connecting a disconnection information control means controlling the disconnection information of the optical fiber transmission line between a remote station and a main station. CONSTITUTION:Whether or not a return signal comes from a remote station (RS) is discriminated. In supplying the reply signal fed from the RS, it is confirmed that an optical fiber transmission line 13 is not disconnected. If no reply signal comes form the RS, a polling error signal is generated to discriminate whether or not a transmission line at the receiving side is opened. When it is discriminated that the transmission line at the receiving side is not opened, the system is in standby for a prescribed time and a main station (MS) 8 is brought into the reception mode by using a control signal fed from the disconnection information control means 14. Whether or not the RS and the MS 8 are connected (restored) again normally is discriminated. In restoring the RS, this processing is finished.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an information transmission device, and more particularly to an information transmission device including an optical PCM digital security relay device.

B0 Summary of the Invention The present invention provides an information transmission device that detects disconnection of an optical fiber transmission line by connecting disconnection information means for controlling disconnection information of the optical fiber transmission line between the n-th remote station and the main station. This makes it easy to monitor information at a central main station, and allows quick restoration of optical fiber transmission lines.

C1 Prior Art A protective relay device for short circuit and ground fault protection usually consists of main protection and back-up protection. Generally, a current differential relay is used for the main protection, and a directional distance relay is used for the backup protection. The current differential relay is a relay that disconnects the faulty part when there is a fault in the microwave line provided between electrical stations. Incidentally, in recent years, optical fiber lines have been widely used as an information transmission medium in place of microwave lines because of their ability to transmit large amounts of information and their strong noise resistance.

FIG. 4 is a block diagram showing an example of an information transmission device using such an optical fiber line.

In this figure, the lines between the codes are busbars, and the power transmission 1fM51 is connected between these busbars. Current transformers 52, 53, 5=4 are inserted into the power transmission line 51, among which the current transformer 52 has a discrimination (relay) circuit % through an A/D converter 55, and the current transformer & An A/D converter 57 is connected to , and a human/D converter μs is connected to current transformer N. The discrimination (relay) circuit I is the main station 59
This is a relay circuit that is connected to enable the transmission and reception of signals. Further, the A/D converter 57 is connected to the first remote station mark, and the M/D converter box is connected to the second remote station 61. The optical fiber transmission line 62 includes a main station 59 . First remote station 6 and second remote station 6
1 is connected. This information transmission device is also equipped with a CPU (not shown) that monitors signal information on the transmission path. This CPU processes one area of the multiplexed frame, for example, the LOOP SV of the frame format shown in FIG.
Monitoring information from each information transmission device is transmitted to the information transmission device (station with master clock) using a line. Such an information transmission device not only enables monitoring at each electrical station, but also enables centralized monitoring.

Furthermore, although the LOOP SV line is assigned to a multiplexed frame, it is originally a loop-connected line. Therefore, in the information transmission apparatus using the present LOOP SV line, transmission control is performed by a central master station.

FIG. 6 is a diagram showing that the present information transmission device employs a polling method. This figure shows that a fixed length amount of information is collected equally from all electrical stations.

D0 Problems to be Solved by the Present Invention However, in such a conventional information transmission device, if the optical fiber transmission line 62 between the first remote station mark and the second remote station 61 is disconnected, as shown in FIG. , the clock information of the optical fiber transmission line 62 is transmitted from the main station 59 to the second remote station 61.
Since the information cannot be transmitted to the main station 59, the information cannot be sent back to the main station 59. In addition, since polling cannot be delivered to the second remote station with such an information transmission device, the main station 59,
There is a problem in that the remote station ω of i1 and the second remote station 61 both generate polling errors, and the main station 59 cannot know the point of disconnection.

The purpose of the present invention is to quickly transmit information on disconnections in optical fiber transmission lines. The purpose of the present invention is to provide an information transmission device that can be obtained with enthusiasm.

Means for Solving the E0 Problem In order to solve the above problem, the present invention provides a main station for monitoring optical information, a first remote station connected to the main station, and an (n-1)th (
n is a natural number of 2 or more], and the n-th remote station is connected to the main station and the first remote station.
An information transmission device comprising an optical fiber transmission line connecting remote stations in a loop, wherein disconnection information control means for controlling disconnection information of the optical fiber transmission line is connected between the n-th remote station and the main station. It is characterized by what it did.

11. Functions This information transmission device allows the LRR line information of the optical fiber transmission line to be easily monitored at the central main station, and the optical fiber transmission line can be quickly restored.

G. Embodiment Next, an embodiment of the information transmission apparatus of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a block diagram showing an embodiment of the information transmission apparatus of the present invention.

In this figure, reference numeral 1 is a bus bar, and connected to this bus bar 1 is a power transmission line 2. Inserted into the power transmission line 2 are current transformers 3, 4.5.

The current transformer 3 passes through the A/D converter 6 to the discrimination (relay) circuit 7
The discrimination circuit 7 is connected to the main station 8. The current transformer 4 passes through an A/D converter 9 to the first
is a current transformer connected to the remote station IO. The current transformer 5 is also connected to a second remote station I2 via an A/D converter 11. The optical fiber transmission line 13 is a transmission line for connection. In this embodiment, a disconnection information control means 14 is further connected to the optical fiber transmission line 13. This disconnection information control means 14 is a circuit that receives disconnection information from the remote station when there is a disconnection between the main station 8 and the remote station.
Based on this disconnection information, for example, a pseudo frame signal is supplied to the main station 8. Although this embodiment also includes a CPU that monitors signal information on the transmission path,
Illustrations are omitted.

Next, the operation of this embodiment will be explained.

FIG. 2 is a flowchart showing the process of the disconnection information control means 14 for restoring the disconnection between the main station and the remote station.

First, a process for restoring the disconnection between the main station 8 and the remote station is started (step 1).

Next, it is determined whether or not there is a return signal from the remote station (R8) side (step 2). If the return signal is supplied from the remote station side, there is no break in the optical fiber transmission line 13. Also, if no return signal is supplied from the remote station side, a polling error signal is generated (step 3).Then, it is determined whether the transmission line on the receiving side is disconnected ( Step 4) If it is determined that the transmission line on the receiving side is not disconnected, the main station (MS) 8 waits for a predetermined time and receives the control signal from the disconnection information control means 14. mode (step 6). Parting, remote station (R8
) and the main station (MS) 8 are normally reconnected (restored) or not (step 7). If the R8 side has been restored, this process is ended (step 8). If it is determined that the remote station side has not been restored normally, the process returns to step 6. If it is determined in step 4 that the receiving optical fiber transmission line 13 is disconnected, the remote station is polled (step 9).

Then, it is determined whether the optical fiber transmission line 13 is disconnected (step 10). Here, if it is determined that the optical 7-IPA transmission line 13 is not disconnected, this process ends (step 8). Further, if it is determined that the optical fiber transmission line 13 is disconnected, step 9
Return to

Next K, IJ mote station and main station 8
The processing process of the disconnection information control means 14 for restoring the disconnection between the lines will be explained.

FIG. 3 is a flowchart showing the process of the disconnection information control means 14 for restoring the disconnection between the remote station and the main station.

First, a process for restoring the disconnection between the second remote station 12 and the main station 8 is started (step 11). Next, the second remote station (R8
2) It is determined whether the optical fiber transmission line 13 between MS 12 and main station (MS) 8 is disconnected (step 12). and a second remote station 12
The optical fiber transmission line 13 between the domain stations 8 is
! When it is determined that there is a 9F line, disconnection information is input from the second remote station I2 to the disconnection information control means 14. The disconnection information control means 14 creates a pseudo frame signal and supplies the pseudo frame signal to the main station 8 (step 13). Next, it is determined whether a polling error occurs at the second remote station 12 (step 14). When it is determined that a polling error occurs, the second remote station 1
2 becomes the polling master (step 15). If it is determined that no polling error has occurred, the process returns to step 13. When the second remote station 12 becomes the polling master in step 15, the second remote station 12 sends the transmission path information to the column main station 8 (step 16). Then, while the optical fiber transmission line 13 is disconnected, disconnection information is supplied from the second remote station 12 to the main station 8 at regular intervals (step 17). Next, the second remote station 12 and the main station 8
It is determined whether the optical fiber transmission line 13 between them has been restored (step 18). If it is determined that the optical fiber transmission line 13 has been restored, transmission line restoration information is supplied from the second remote station 12 to the main station 8 (step 19), and this process ends (step 20). Further, if it is determined that the optical fiber transmission line 13 has not been restored, step 16
-> Return. Similarly, in step I2 above, the second remote station (R82) 12 and the main station (MS)
The optical fiber transmission line 13 between 8 is 11! l? If it is determined that there is no line, the process immediately ends (step 20).

In the information transmission device of this embodiment, the disconnection information of the optical fiber transmission line 13 is supplied to the main station 8 only from the upper remote station, so the disconnection information of the optical fiber transmission line 13 can be monitored from the central main station. 9, and the optical fiber transmission line 13 can be quickly restored.

Furthermore, in the information transmission device of this embodiment, when there is a break in the optical fiber transmission line 13, it is possible to obtain break information and supply a pseudo frame signal to the main station 8. A break in the optical fiber transmission line 13 can be confirmed.

Effects of the H0 Invention As described above, according to the present invention, it becomes easy to monitor the disconnection information of the optical fiber transmission line at the central main station, and the optical 7-IPA transmission line can be quickly restored.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the information transmission device of the present invention, FIG. 2 is a flowchart showing the processing process of the disconnection information control means for recovering the disconnection between the main station and the remote station, and FIG. FIG. 4 is a block diagram showing an example of a conventional information transmission device; and FIG. Figure 6 is a diagram showing that the information transmission device adopts the polling method, and Figure 7 is a diagram showing that the conventional information transmission device has a disconnection between R8I and R8.
It is a diagram showing what happened between the two. 1... Bus bar, 2... Power transmission line, 3, 4, 5... Current transformer, 6... A/D converter, 7... Discrimination (relay) circuit, 8... Main Station, 9 people/D
Transducer, 10...first remote station, 11
... A/D converter, 12... Second remote station, 13... Optical fiber transmission line, 14...
・Disconnection information control means. Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 LOOP SV l'fl Figure 6 Figure 7

Claims (1)

[Claims] a main station that monitors optical information; a first remote station connected to the main station;
An n-th remote station connected to the (n-1)th (n is a natural number of 2 or more) remote station, and an optical fiber loop-connecting the n-th remote station from the main station and the first remote station. 1. An information transmission device comprising a transmission line, characterized in that a disconnection information control means for controlling disconnection information of the optical fiber transmission line is connected between the n-th remote station and the main station.