JPH01274525A - Optical fiber switching circuit - Google Patents

Abstract

PURPOSE:To improve the utilizing efficiency of a transmission line by using a submarine branch device to switch the transmission line and using a section without no fault for the transmission line between other land stations if a fault takes place in the optical fiber transmission line between the land station and the submarine repeater in the optical submarine relay system. CONSTITUTION:When the connection of the transmission line is normal, contacts a, b of each optical switch are connected and land stations A, B are connected by optical switches SW6, 2, 1, 5 and land stations B, C are connected by switches SW 3, 10, 9, 4 and land stations A, C are connected by SW 11, 7, 8, 12. If a fault takes place in the land station A, the connection of the contacts a, c is commanded by a command A1 of the land station B and the command A2 from the land station C and the branches between the B, C are connected by the SW3, 10, 9, 4 and SW 1, 12, 11, 2. If a fault takes place in the B or C, the SWs are selected properly.

Description

[Detailed Description of the Invention] [Summary] Regarding an optical fiber switching circuit for switching optical fibers in the event of a failure in an optical underwater branching system, when a failure occurs in the optical fiber transmission line between a landing station and an underwater branching device. , an optical underwater branch system that is installed underwater and interconnects multiple landing stations via a transmission line, with the purpose of using the fault-free section of the transmission line as a transmission line between other landing stations. In the optical fiber switching circuit in the underwater branching equipment of A switch control circuit is provided in each transmission line leading to the landing station and controls switching of each of the changeover switches according to control signals sent from at least two landing stations via the transmission line. The transmission lines leading to each landing station are connected to each other, and in the event of a failure in the transmission line leading to any one landing station, the transmission lines leading to the other two landing stations connected to the transmission line are connected to each other. The two landing stations are configured by being interconnected to form a line between the two landing stations.

[Industrial application field]

The present invention relates to an optical fiber switching circuit for switching optical fibers in the event of a failure in an optical underwater branching system.

In the optical submarine cable system, a cable that accommodates a large number of optical fibers in one cable takes advantage of the fine core nature of optical fibers, and the connections of the optical fibers are switched at an underwater branching device installed under the sea. A method of branching is adopted.

In such an optical underwater branching system, if a failure occurs in the optical fiber transmission line between the landing station and the underwater branching equipment, the optical fiber transmission line is switched at the underwater branching equipment, and the failure in that transmission line is resolved. It is desirable to be able to use the section where no such noise occurs as a transmission path between other landing stations.

[Conventional technology]

Figure 13 shows a schematic configuration of the optical submarine branching system, in which landing stations A, B, and C installed on land connect optical submarine cables via underwater branching equipment BU installed on the seabed. It is shown that it is connected via. As described above, the optical submarine cable in this case is composed of an optical fiber transmission line made up of a large number of optical fibers and a power supply line.

Furthermore, FIG. 14 shows a configuration example of a conventional optical fiber switching circuit in an underwater branching device, in which SW1 to SW6 are optical switches, BS1 and 2 are beam splitters, SC1,
2 is a switch control circuit that performs switching control of each optical switch SW1-SW6. Switch control circuits SC1 and SC2 perform switching control in accordance with switching control commands C and B given from landing stations B and C, respectively.

FIG. 15 shows the functions of switching control commands B and C given to each switch control circuit SC1 and SC2,
Command C is sent to landing station B via beam splitter BS1.
Command B is applied from landing station C to switch control circuit SC2 via beam splitter BS2. Switching control commands B, C
are composed of codes instructing the respective control contents, and the switch control circuits SC2 and SC1 decode these codes and perform the function of switching each switch as shown in FIG. 15, respectively.

Each of the optical switches SW1 and SW2 performs connections a and b when normal, and connects a and c when switched. Further, the optical switch SW3.4 connects a to c during normal operation, and connects a to b when switched. Furthermore, optical switch S
W5.6 performs an a-c connection during normal operation, and performs an a-b or d-c connection when switched.

When the transmission path is normal, optical switches SW1 and SW2 connect landing stations A and B, optical switch SW5.6 connects landing stations B and C, and optical switch SW3.4 connects landing stations C and B. A is connected.

When landing station B side branch failure occurs, command B causes S
It instructs W1 and 2 to connect a-c, and instructs SW5.6 to connect d-c. Therefore, the optical switch SW
3.4, the connection between landing stations C and A is maintained, and the branch on the landing station C side and the branch on the landing station A side, which were connected to the failed branch on the B side, are connected to the optical switch SW.
Connected by 6,1°2.5.

When landing station C side branch fails, S
Instruct W3.4.5.6 to connect a-b. Therefore, the connection between landing stations A and B is maintained by optical switch SW1.2, and the branch on the landing station A side and the branch on the landing station B side, which were connected to the failed branch on the C side, are optically connected. Connected by switch SW4, 6.5.3.

The connection between 0 and 0 is maintained.

[Problems to be Solved by the Invention] In the conventional optical fiber switching circuit shown in FIG. A new line can be constructed by connecting the transmission line between station C or B and the underwater branching device BU to the landing station A via the underwater branching device BU.

However, if a transmission path failure occurs between landing station A and underwater branching device BU, the transmission path between landing station B or C and underwater branching device BU is switched to the transmission path between landing stations B and C. There was a problem that it could not be used for

The present invention is an attempt to solve the problems of the prior art as described above, and when a failure occurs in the optical fiber transmission line between the landing station and the underwater branching device, the underwater branching device switches the optical fiber transmission line. By doing this, the aim is to make it possible to use sections where failures have not occurred as transmission lines between other landing stations.

[Means to solve the problem]

The optical fiber switching circuit of the present invention is an optical fiber switching circuit in an underwater branching device of an optical underwater branching method that is installed underwater and interconnects a plurality of landing stations via a transmission line, and includes a changeover switch SW1. ~10, 11.12 are provided on the transmission lines leading to each landing station, and switch control circuits SC1, 2.3 are provided, and during normal operation, the transmission lines leading to each landing station are connected to each other. In addition, in the event of a failure in the transmission line leading to any one landing station, the transmission lines leading to the other two landing stations that were connected to that transmission line are interconnected to connect the two landing stations. It is possible to configure a line of

The changeover switches SW1 to SW10, 11, and 12 can switch and connect a transmission path leading to one landing station to a changeover switch inserted in a transmission path leading to two other landing stations.

The switch control circuits SC1, 2.3 perform switching control of each changeover switch in response to control signals sent from at least two landing stations via transmission lines.

[For production]

In the optical underwater branching system, an underwater branching device is installed underwater, and a plurality of landing stations are interconnected via transmission lines. The underwater branching device is equipped with an optical fiber switching circuit, and performs optical fiber switching control to establish the required line configuration both in normal operation and in the event of a failure in the transmission line leading to any landing station.

In the optical fiber switching circuit, the switch control circuit SC1
, 2.3 are changeover switches SW1 to SW10.1 in response to control signals sent from at least two landing stations via transmission lines.
1.12 switching control is performed. Changeover switch SW1~10
．． 11 and 12 are installed on each transmission line leading to each landing station, and the transmission line leading to one landing station is switched to the changeover switch inserted in the transmission line leading to the other two landing stations. configured so that it can be connected.

Therefore, during normal operation, the transmission lines leading to each landing station are connected to each other to form a line between each landing station, and
In the event of a failure in the transmission line leading to one of the landing stations, the transmission lines leading to the other two landing stations that were connected to that transmission line are interconnected to connect these two landing stations. Therefore, it is possible to configure a line by using the unfaulted section of the transmission line as a transmission line between other landing stations, and improve the efficiency of using the transmission line. become.

〔Example〕

FIG. 1 shows an embodiment of the optical fiber switching circuit of the present invention, in which SW1 to SW12 are optical switches,
SW5, 6, 7.8 are inserted for the landing station A side branch, SW1, 2, 3.4 are inserted for the landing station B side branch, and SW9°10, 11.12 are inserted for the landing station B side branch. It is inserted for the branch on the station C side. Further, BS1 to 4 are beam splitters, and SC1 to SC3 are switch control circuits that perform switching control of the optical switches SW1 to SW12.

FIG. 2 shows the functions of the switching control commands given to each switch control circuit, and shows the commands Bl, C2.
are given to the switch control circuit S01 from landing stations B and C via beam splinters BS1 and BS3, respectively, and commands B2. A2 is given from landing station C to switch control circuit SC2 via beam splinter B5-4, and command AI.

C is provided from landing station B to switch control circuit SC3 via beam splinter BS2. Each command performs the switching function of the optical switch shown in the second diagram. Each optical switch normally connects a and b, and when switched, connects a and c.

The operation of the optical fiber switching circuit shown in FIG. 1 will be explained below.

(1) When the transmission line is normal FIG. 3 shows the connection state when the transmission line is normal, and in this case, each optical switch is in the a-b connection state. Therefore, landing stations A and B are connected by optical switch SW6゜2.1.5, and optical switch SW3.10,9
．． Landing station B by 4.

0 are connected, and the optical switches 5WI1, 7. 8.
By connecting landing stations C and A by 12 degrees, the connection state shown in FIG. 3 is achieved.

(2) Landing station A side branch failure Figure 4 shows the connection status when landing station A side branch failure occurs. In this case, the command A1 from landing station B is
, command A2 from landing station C both indicate the connection status of a-c.

Therefore, the optical switch SW3, 10.9.4 maintains the connection between landing stations B and C, and the branch on the landing station B side that was connected to the faulty branch on the landing station A side and the landing station. The branch on the C side is the optical switch SW1, 12.
11. Connected by 2.

(3) When the landing station B side branch fails Figure 5 shows the connection state when the landing station B side branch fails. In this case, the command Bl from the landing station C is
, B2 indicate the connection status of a-c.

Therefore, the connection between landing stations C and A is maintained by the optical switches 5WI1 and 7.8.12, and the branch on the landing station C side that was connected to the faulty branch on the landing station B side and the landing station The branch on the A side is the optical switch SW9,5.6
．． connected by 10.

(4) Landing station C side branch failure Figure 6 shows the connection status when landing station C side branch failure occurs. In this case, the command C1 from landing station B
, C2 indicate the connection status of a-c.

Therefore, by optical switch SW6, 2.1.5, landing station A is
, B is maintained, and the branch on the landing station A side and the branch on the landing station B side, which were connected to the failed branch on the landing station C side, are connected to the optical switch SW8.4, 3. 7
connected by.

FIG. 7 shows another embodiment of the optical fiber switching circuit of the present invention, in which SW1 to SW10 are optical switches, and SW1 and 2.3.4 are for the branch on the landing station A side. SW7.8, 5.6 are inserted for the landing station B side branch, and SW6.5.9.10 is inserted for the landing station C side branch. Further, BS1 to 3 are beam splitters, and SC1 and SC2 are switch control circuits.

FIG. 8 shows the functions of the identification codes given to each switch control circuit, where the identification code f1 is transmitted from the landing station C via the beam splitter BS2, and the identification code f2 is transmitted from the landing station C via the beam splitter BSI. The identification code f3 is applied from the landing station C to the switch control circuit S01, and the identification code f3 is applied from the landing station B to the switch control circuit SC2 via the beam splitter BS3. The identification code is, for example, a modulation signal of a transmission line signal, and is demodulated in each switch control circuit to perform the switching function of the optical switch shown in FIG.

Each optical switch SW1.2.7.8, 9.10 always connects a to b, and when switched, a
- Connect c. Also, optical switch SW3.4 is always a
-c is connected, and when switched, a-b is connected. Furthermore, the optical switch SW5.6 normally performs a-c connection, and when switched, performs a-b or c-d connection.

The operation of the optical fiber switching circuit shown in FIG. 7 will be explained below.

(1) When the transmission line is normal FIG. 9 shows the connection state when the transmission line is normal, and in this case, each optical switch is in a normally connected state. Therefore, optical switches SW2, 8.7.1 connect landing stations A and B, optical switch SW5.6 connects landing station 8.0, and optical switches SW9, 3.
4.10, the landing stations C and A are connected, resulting in the connection state shown in FIG. 9.

(2) Landing station A side branch failure Figure 10 shows the connection state when landing station A side branch failure occurs. In this case, the identification code f from landing station B.
3 instructs SW7.8 and SW9.10 about the connection status of a-c.

Therefore, landing station B is set by optical switch SW5.6.

At the same time, the branch on the landing station B side and the branch on the landing station C side, which were connected to the failed branch on the landing station A side, are switched to optical switches SW7.10 and 9.8.
connected by.

(3) Landing station B side branch failure Figure 11 shows the connection status when landing station B side branch failure occurs. In this case, the identification code f from landing station C.
1 indicates the connection state of a-C to SW1, 2, and indicates the connection state of a-b to SW5.6.

Therefore, the connection between landing stations C and A is maintained by optical switch SW9.3.4.10, and the branch on the landing station C side that was connected to the faulty branch on the landing station B side and the landing station The branch on the A side is the optical switch SW6.1.2.
Connected by 5.

(4) Landing station C side branch failure Figure 12 shows the connection status when landing station C side branch failure occurs. In this case, the identification code f from landing station B
2 instructs SW 3.4 about the connection state of a and b, and instructs SW 5.6 about the connection state of C and d.

Therefore, by using optical switches SW2, 8, and 7.1, landing station A is
, B is maintained, and the branch on the landing station A side and the branch on the landing station B side, which were connected to the failed branch on the landing station C side, are switched to optical switch SW4.6.5. 3
connected by.

〔Effect of the invention〕

As explained above, according to the present invention, when a failure occurs in the optical fiber transmission line between the landing station and the underwater branching device in the optical underwater branching system, the optical fiber transmission line is switched at the underwater branching device. , it becomes possible to configure a line by using sections of the transmission line in which no faults have occurred as transmission lines between other landing stations, thereby improving the efficiency of use of the transmission line.

[Brief explanation of the drawing]

Figure 1 is a diagram showing an embodiment of the optical fiber switching circuit of the present invention, Figure 2 is a diagram showing the functions of switching control commands given to each switch control circuit in the circuit of Figure 1, and Figure 3 is a diagram showing an embodiment of the optical fiber switching circuit of the present invention. Figures 4 to 6 are diagrams showing the connection state in the circuit of Figure 1 during normal operation, respectively. 7 is a diagram showing another embodiment of the optical fiber switching circuit of the present invention, FIG. 8 is a diagram showing the function of the identification code given to each switch control circuit in the circuit of FIG. 2, and FIG. Figures 10 to 12 are diagrams showing the connection states of the circuit shown in Figure 7 during normal operation; Figures 10 to 12 are diagrams showing the connection states of the landing station A, B, and C side branch failures in the circuit of Figure 7; Figure 13; Figure 14 shows the schematic configuration of the optical underwater branching system.
15 is a diagram showing a configuration example of a conventional optical fiber switching circuit, and FIG. 15 is a diagram showing the function of a switching control command in the circuit of FIG. 14. SW1~12--Optical switch BS1-4-/Beam splitter S01-3...Switch control circuit

Claims (1)

[Claims] In an optical fiber switching circuit in an underwater branching device of an optical underwater branching system that is installed under the sea and interconnects a plurality of landing stations via a transmission line, the transmission leads to one landing station. A changeover switch (SW1 to SW10, 11, 12) that can be connected to the changeover switch inserted in the transmission path leading to the other two landing stations is provided on each transmission path leading to each landing station. , comprising a switch control circuit (SC1, 2, 3) that performs switching control of each of the changeover switches according to control signals sent from at least two landing stations via transmission lines, and in normal operation, each landing station In addition, in the event of a failure in the transmission line leading to one of the landing stations, the transmission lines leading to the other two landing stations connected to that transmission line are interconnected. An optical fiber switching circuit characterized in that it can configure a line between the two landing stations.