JP2000269891A - Optical line concentrator and method for switching active system/standby system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To build up a passive double star PDS method optical communication system where the installation investment cost is suppressed and a communication service with high reliability is served in an optical line concentrator in the PDS method communication system and a changeover method of active system/ standby system. SOLUTION: The optical line concentrator 1 where many user devices are connected via an optical transmission line 22 and an optical star coupler 23, is provided with two optical transmission systems 2, 3 that transmit an optical signal to the optical star coupler 23 and with changeover means 4-8 that switch an active system transmission line to a standby system transmission line for the optical transmission lines 25, 26 between each of the two optical transmission systems 2, 3 and the optical star coupler 23.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical concentrator in a passive double star (PDS: Passive Double Star) optical communication system and a method for switching between an active system and a standby system.

2. Description of the Related Art FIG. 2 is a block diagram showing the configuration of a conventional PDS optical communication system. In FIG. 2, PD
The S-type optical communication system has a configuration in which an optical line concentrator 20 and a number of user devices 21 are connected via an optical transmission line 22, an optical star coupler 23, and an optical transmission line 24.

In this system, a large number of user devices 21
Are multiplexed by the optical star coupler 23 and sent out to one optical fiber 24, and the optical concentrator 20 sends them out to the network. Further, the optical concentrator 20 sends the transmission signal sent from the network to one optical fiber 24, and
3 are separated and transmitted to an optical transmission line 22 for a plurality of user devices 21.

[0003] That is, since the PDS optical communication system is an access system, one of its missions is to be able to provide inexpensive communication services to users.
There is a strong demand that capital investment costs for communication systems be reduced.

[0004] Therefore, the optical concentrator 20 receives the transmission signal transmitted from the optical star coupler 23 and the optical transmission unit for transmitting the transmission signal transmitted from the network toward the optical star coupler 23, and transmits the transmission signal to the network. An optical receiving unit for transmitting the optical signal to the user device 21 is provided. However, the entire structure from the optical concentrator 20 to the user device 21 has a single configuration as shown in FIG. 2, for example. Was common.

[0005]

By the way, in recent years, with the rapid progress of the information society, the provision of more reliable communication services has been required, and the conventional PDS type optical communication which does not employ a duplex structure has been required. In systems, measures to increase the reliability of communication services have become necessary.

However, in order to provide a highly reliable communication service, Japanese Patent Application Laid-Open Nos. 7-250028 and 8
As disclosed in JP-A-307361 and JP-A-9-116491, if the entire optical communication system is duplicated, the cost of capital investment becomes large, and there is a demand that communication services be provided at low cost. It becomes difficult to respond to.

SUMMARY OF THE INVENTION An object of the present invention is to provide a PD capable of suppressing a capital investment cost and providing a highly reliable communication service.
An object of the present invention is to provide an optical line concentrator and a method for switching between an active system and a standby system, which enable construction of an S-system optical communication system.

[0008]

The optical concentrator according to the first aspect of the present invention is an optical concentrator in which a number of user devices are connected via an optical transmission line and an optical star coupler, respectively. An optical transmission system for transmitting an optical signal toward an optical star coupler is provided in two sets, and an optical transmission path between each of the two sets of optical transmission systems and the optical star coupler is provided.
Switching means for switching from the working transmission line to the protection transmission line is provided.

According to the first aspect of the present invention, at least the transmission system of the optical concentrator is duplicated, and the optical transmission path to the optical star coupler can be switched in the optical concentrator. Therefore, the reliability of the communication service can be improved while minimizing the capital investment.

According to a second aspect of the present invention, in the optical concentrator according to the first aspect, the switching unit monitors an operation state of a transmission system operating as a standby system. And a control means for controlling the switching operation based on a switching command input from the outside and an output of the monitoring means.

According to the second aspect of the present invention, the switching is executed after confirming the normality of the transmitting system operating as the standby system. Therefore, the reliability of the communication service can be reliably increased.

According to a third aspect of the present invention, in the optical concentrator according to the second aspect, the monitoring means includes an input port connected to an output port of the optical transmission system via an optical transmission line. And one of the two output ports, one of the output ports being connected to the optical star coupler via an optical transmission line, and receiving one of the control signals from the control means. Two optical switches which connect an input port to one output port to be a working system and connect the other optical switch to an input port and the other output port to be a standby system; and the two optical switches And two light receiving means for receiving the output light of the other output port.

According to the third aspect of the present invention, the monitoring means constituting the switching means can be configured at a low cost, so that an increase in cost can be suppressed to a minimum.

According to a fourth aspect of the present invention, there is provided a method for switching between an active system and a standby system, wherein a passive double star type optical system connects an optical concentrator and a number of user devices via an optical transmission line and an optical star coupler. In the communication system, the optical concentrator at least switches an optical transmission line between each of the duplicated optical transmission systems and the optical star coupler from a working transmission line to a protection transmission line. I do.

According to a fifth aspect of the present invention, in the method for switching between the active system and the standby system according to the fourth aspect, the operation state of the transmitting system operating as the standby system is monitored. The switching operation is controlled based on a switching command input from the outside and the monitoring result.

[0016]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of an optical concentrator according to an embodiment corresponding to claims 1 to 5. In FIG. 1, the optical line concentrator 1 includes a 0-system transmitting unit 2 and a 1-system transmitting unit 3 as an optical transmitting unit that transmits a transmission signal S1 sent from a network toward an optical star coupler 23.

The output port of the 0-system transmitting section 2 is connected to the input port of the 0-system optical switch 4, and the 1-system transmitting section 3 is connected to the input port of the 1-system optical switch 5. The 0-system optical switch 4 has one output port A connected to one input port of the optical star coupler 23 via the optical transmission line 25, and the other output port B connected to a 0-system photodiode (hereinafter referred to as “0-system P
D ”) 6 input ports.

In the first-system optical switch 5, one output port A is connected to the other input port of the optical star coupler 23 via the optical transmission line 26, and the other output port B is connected to the first-system photodiode (hereinafter referred to as "the photodiode"). 7 (referred to as “1 system PD”). Output ports of the 0-system PD 6 and the 1-system PD 7 are connected to one input port of the monitoring control unit 8, respectively. In the monitoring controller 8, a switching command is input from the outside to the other input port, and the output port is connected to the control ports of the two optical switches 4 and 5.

The relationship between the above configuration and the claims is as follows. The optical concentrator 1 corresponds to the optical concentrator. The 0-system optical transmission unit 2 and the 1-system optical transmission unit 3 correspond to the two sets of optical transmission systems. Optical transmission paths 25 and 26 correspond to optical transmission paths between each of the two sets of optical transmission systems and the optical star coupler. The entirety of the 0-system optical switch 4, the 1-system optical switch 5, the 0-system PD 6, the 1-system PD 7, and the monitoring control unit 8 correspond to the switching means.

Next, the operation of this embodiment will be described with reference to FIG. In FIG. 1, electrical transmission data S1 input from the network to the optical concentrator 1 is input to the 0-system optical transmission unit 1 and the 1-system optical transmission unit 2.

The 0-system optical transmission unit 1 converts the input electric transmission data S1 into an optical signal S2 and outputs it to the optical switch 4. The first-system optical transmission unit 2 converts the input electric transmission data S1 into an optical signal S3 and outputs the optical signal S3 to the optical switch 5.

The 0-system optical switch 4 and the 1-system optical switch 5 are
The input port is connected to one of the output ports A and B by the control signal S4 from the monitoring control unit 8. Monitoring control unit 8
Generates the switching control signal S4 based on the monitor signal S5 output from the 0-system PD6 and the monitor signal S6 output from the 1-system PD7.

For example, when the 0-system optical transmission unit 1 is a working system and the 1-system optical transmission unit 2 is a standby system, the monitoring control unit 8 sends the switching control signal S4 to the 0-system optical switch 4 The output is connected to the output port A, and the first-system optical switch 5 is connected to the input port to the output port B.

That is, the 0-system optical switch 4 sends the input optical signal S2 from the output port A to the optical star coupler 23 via the optical transmission line 25, and the 1-system optical switch 5 converts the input optical signal S3. The signal is transmitted from the output port B to the first system PD 7. In this operation state, the 0-system PD 6 does not input the optical signal S2 output from the 0-system optical transmission unit 1 operating as the active system, and outputs the 0-level monitor signal S5 to the monitoring control unit 8. . On the other hand, the first-system PD 7 receives the optical signal S3 output from the first-system optical transmission unit 2 operating as the standby system, and outputs a monitor signal S6 of a level corresponding to the reception state to the monitoring control unit 8.

The monitoring control unit 8 can determine which of the system 0 and the system 1 is the working system. Therefore, the monitoring control unit 8 monitors the signal levels of the monitor signals S5 and S6, thereby transmitting the protection system optical transmission signal. The normality of the part can be confirmed. When a transmission error occurs in the 0-system optical transmission unit 1 operating as the active system, a switching command is externally input to the monitoring control unit 8.

When a switching command is input from the outside, the monitoring control unit 8 confirms whether or not the 1-system optical transmission unit 2 operating as the standby system is normal based on the signal level of the standby monitor signal S6. In some cases, the optical switch 5 generates a switching control signal S4 for connecting the input port to the output port A and causing the optical switch 4 to connect the input port to the output port B. As a result, switching between the active system and the standby system is performed.

In FIG. 1, since the reliability when transmitting a transmission signal from the network to the user equipment often becomes a problem, the optical concentrator 1 requires a route from the user equipment to the network. Although not shown, an optical receiver is naturally provided. At this time, it is possible to use one optical receiver by switching with an optical switch. However, since the optical switch is expensive, it is necessary to correspond to the 0-system optical transmitter 2 and the 1-system optical transmitter 2. It is preferable to provide 0-system and 1-system optical receiving units.

Further, the 0-system PD 6 and the 1-system PD 7 can be used together by switching them with one optical switch. However, as described above, the optical switch is expensive, It is provided in.

[0030]

As described above, according to the first aspect of the present invention, in an optical concentrator in a PDS type optical communication system, an optical signal transmission system and a route from the optical signal transmission system to an optical star coupler. Since only one of them is duplicated, the cost of capital investment can be suppressed and a PDS optical communication system capable of providing a highly reliable communication service can be constructed.

According to the second aspect of the present invention, the switching is executed after confirming the normality of the transmitting system operating as the standby system, so that the reliability of the communication service can be reliably improved. .

According to the third aspect of the present invention, the monitoring means constituting the switching means can be configured at a low cost, so that an increase in cost can be suppressed to a minimum.

[Brief description of the drawings]

FIG. 1 is a configuration block diagram of an optical concentrator according to an embodiment of the present invention.

FIG. 2 is a configuration block diagram of a conventional PDS optical communication system.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 optical concentrator 2 0-system optical transmission unit 3 1-system optical transmission unit 4 0-system optical switch 5 1-system optical switch 6 0-system photodiode (0-system PD) 7 1-system photodiode (1-system PD) 8 monitoring control unit 21 user Device 22 Optical transmission line 23 Optical star coupler

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[Procedure amendment]

[Submission date] February 21, 2000 (200.2.2
1)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

Patent application title: Optical concentrator and method for switching between active and standby systems

[Claims]

1. A large number of user devices, each optical transmission line及
And an optical signal is transmitted to at least the optical star coupler.
Two sets of optical transmission systems are provided, each of the two sets of optical transmission systems and the optical star coupler.
The optical transmission line between the active transmission line and the protection transmission line
In optical line device provided with switching means for switching to the switching means, monitoring means for monitoring the operating state of the transmission system operating as a standby system, the protection system of the switch command signal and said monitoring means for inputting from outside
Control means for controlling the switching operation based on an output indicating that the transmission system operating as a normal is operating.

2. The optical line concentrator according to claim 1 , wherein said monitoring means has an input port connected to an output port of said optical transmission system via an optical transmission line, and one of two output ports. Are two optical switches connected to the optical star coupler via an optical transmission line, and one optical switch receives an input port and one output port in response to a control signal from the control means. The two optical switches are connected to each other to form a working system, and the other optical switch connects an input port and the other output port to form a standby system, and receives output light from the other output port of each of the two optical switches. An optical concentrator, comprising: two light receiving units.

3. A passive double-star optical communication system for connecting an optical concentrator and a number of user devices via an optical transmission line and an optical star coupler, wherein the optical concentrator comprises at least a duplicated optical transmission system. The optical transmission line between each of them and the optical star coupler is used as a standby system to monitor the operating state of the transmitting system.
Based on the switching command input from outside and the result of the monitor.
A method for switching between the active system and the standby system, wherein the active system is switched to the standby system.

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical concentrator in a passive double star (PDS: Passive Double Star) optical communication system and a method for switching between an active system and a standby system.

[0002]

2. Description of the Related Art FIG. 2 is a block diagram showing the configuration of a conventional PDS optical communication system. In FIG. 2, PD
The S-type optical communication system has a configuration in which an optical line concentrator 20 and a number of user devices 21 are connected via an optical transmission line 22, an optical star coupler 23, and an optical transmission line 24.

In this system, a large number of user devices 21
Are multiplexed by the optical star coupler 23 and sent out to one optical fiber 24, and the optical concentrator 20 sends them out to the network. Further, the optical concentrator 20 sends the transmission signal sent from the network to one optical fiber 24, and
3 are separated and transmitted to an optical transmission line 22 for a plurality of user devices 21.

[0004] In other words, since the PDS optical communication system is an access system, one of its missions is to provide inexpensive communication services to users.
There is a strong demand that capital investment costs for communication systems be reduced.

Therefore, the optical concentrator 20 receives the transmission signal transmitted from the optical star coupler 23 and the optical transmission unit for transmitting the transmission signal transmitted from the network toward the optical star coupler 23, and transmits the transmission signal to the network. An optical receiving unit for transmitting the optical signal to the user device 21 is provided. However, the entire structure from the optical concentrator 20 to the user device 21 has a single configuration as shown in FIG. 2, for example. Was common.

[0006]

By the way, in recent years, with the rapid progress of the information society, the provision of more reliable communication services has been required, and the conventional PDS type optical communication which does not employ a duplex structure has been required. In systems, measures to increase the reliability of communication services have become necessary.

However, in order to provide a highly reliable communication service, Japanese Patent Application Laid-Open Nos. 7-250028 and 8
As disclosed in JP-A-307361 and JP-A-9-116491, if the entire optical communication system is duplicated, the cost of capital investment becomes large, and there is a demand that communication services be provided at low cost. It becomes difficult to respond to.

SUMMARY OF THE INVENTION An object of the present invention is to provide a PD capable of suppressing a capital investment cost and providing a highly reliable communication service.
It is to provide a form of optical line terminal and the switching method of working / standby enabling the construction of S type optical communication system.

[0009]

Optical line terminal according to the invention of claim 1 SUMMARY OF THE INVENTION, multiple user devices are connected via the optical transmission path and the optical star coupler, at least,
Two sets of optical transmission systems for transmitting an optical signal toward the optical star coupler are provided, and an optical transmission line between each of the two sets of optical transmission systems and the optical star coupler is set up from a working transmission line. Concentrator provided with switching means for switching to a system transmission line
, The switching means is operating as a standby system
Monitoring means for monitoring the operation status of the transmission system and external
It operates as a switching command signal to be input and as a standby system of the monitoring means.
Based on the output indicating that the transmitting system being made is normal,
Control means for controlling the switching operation.
You.

According to the first aspect of the present invention , at least the transmission system of the optical concentrator is duplicated, and the optical transmission path to the optical star coupler can be switched in the optical concentrator. Thus, while minimizing capital investment, Ru Tei increases the reliability of communications services.

[0011] In particular, the switching means, monitoring means for monitoring the operating state of the transmission system operating as a standby system,
It you are characterized and control means for controlling the switching operation based on the output of the monitoring means and switching command input from the outside.

[0012] According to the first aspect of the present invention, from the outside
It operates as a switching command signal to be input and as a standby system of the monitoring means.
Based on the output that the transmission system you are making is normal,
That is, switching is performed after confirming the normality of the transmission system operating as the standby system. Therefore, the reliability of the communication service can be reliably increased.

According to a second aspect of the present invention, in the optical concentrator according to the first aspect , the monitoring means includes an input port connected to an output port of the optical transmission system via an optical transmission line. And one of the two output ports, one of the output ports being connected to the optical star coupler via an optical transmission line, and receiving one of the control signals from the control means. Two optical switches which connect an input port to one output port to be a working system and connect the other optical switch to an input port and the other output port to be a standby system; and the two optical switches And two light receiving means for receiving the output light of the other output port.

According to the second aspect of the present invention, since the monitoring means constituting the switching means can be configured at a low cost, the increase in cost can be suppressed to a minimum.

According to a third aspect of the present invention, there is provided a method for switching between an active system and a standby system, wherein a passive double star optical system connects an optical concentrator and a number of user devices via an optical transmission line and an optical star coupler. In the communication system, at least the optical concentrator has an optical transmission path between each of the duplicated optical transmission systems and the optical star coupler as a standby system.
Monitor the operating status of the operating transmission system, and
The transmission line is switched from the active transmission line to the standby transmission line based on the input switching command and the result of the monitor .

[0016]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of an optical concentrator according to an embodiment corresponding to claims 1 to 5. In FIG. 1, the optical line concentrator 1 includes a 0-system transmitting unit 2 and a 1-system transmitting unit 3 as an optical transmitting unit that transmits a transmission signal S1 sent from a network toward an optical star coupler 23.

The output port of the 0-system transmitting section 2 is connected to the input port of the 0-system optical switch 4, and the 1-system transmitting section 3 is connected to the input port of the 1-system optical switch 5. The 0-system optical switch 4 has one output port A connected to one input port of the optical star coupler 23 via the optical transmission line 25, and the other output port B connected to a 0-system photodiode (hereinafter referred to as “0-system P
D ”) 6 input ports.

In the first-system optical switch 5, one output port A is connected to the other input port of the optical star coupler 23 via the optical transmission line 26, and the other output port B is connected to the first-system photodiode (hereinafter referred to as "the photodiode"). 7 (referred to as “1 system PD”). Output ports of the 0-system PD 6 and the 1-system PD 7 are connected to one input port of the monitoring control unit 8, respectively. In the monitoring controller 8, a switching command is input from the outside to the other input port, and the output port is connected to the control ports of the two optical switches 4 and 5.

The relationship between the above configuration and the claims is as follows. The optical concentrator 1 corresponds to the optical concentrator. The 0-system optical transmission unit 2 and the 1-system optical transmission unit 3 correspond to the two sets of optical transmission systems. Optical transmission paths 25 and 26 correspond to optical transmission paths between each of the two sets of optical transmission systems and the optical star coupler. The entirety of the 0-system optical switch 4, the 1-system optical switch 5, the 0-system PD 6, the 1-system PD 7, and the monitoring control unit 8 correspond to the switching means.

Next, the operation of this embodiment will be described with reference to FIG. In FIG. 1, electrical transmission data S1 input from the network to the optical concentrator 1 is input to the 0-system optical transmission unit 1 and the 1-system optical transmission unit 2.

The 0-system optical transmission unit 1 converts the input electric transmission data S1 into an optical signal S2 and outputs it to the optical switch 4. The first-system optical transmission unit 2 converts the input electric transmission data S1 into an optical signal S3 and outputs the optical signal S3 to the optical switch 5.

The 0-system optical switch 4 and the 1-system optical switch 5 are
The input port is connected to one of the output ports A and B by the control signal S4 from the monitoring control unit 8. Monitoring control unit 8
Generates the switching control signal S4 based on the monitor signal S5 output from the 0-system PD6 and the monitor signal S6 output from the 1-system PD7.

For example, when the 0-system optical transmission unit 1 is a working system and the 1-system optical transmission unit 2 is a standby system, the monitoring control unit 8 sends the switching control signal S4 to the 0-system optical switch 4 The output is connected to the output port A, and the first-system optical switch 5 is connected to the input port to the output port B.

That is, the 0-system optical switch 4 sends the input optical signal S2 from the output port A to the optical star coupler 23 via the optical transmission line 25, and the 1-system optical switch 5 converts the input optical signal S3. The signal is transmitted from the output port B to the first system PD 7. In this operational state, the 0-system PD6, optical signal S2 which is 0-system optical transmission unit 1 which operates as a working system output is not input, and outputs the 0 level of the monitor signal S5 to the monitoring control unit 8 I have. On the other hand, the first-system PD 7 receives the optical signal S3 output from the first-system optical transmission unit 2 operating as the standby system, and outputs a monitor signal S6 of a level corresponding to the reception state to the monitoring control unit 8.

The monitoring control unit 8 can determine which of the system 0 and the system 1 is the working system. Therefore, the monitoring control unit 8 monitors the signal levels of the monitor signals S5 and S6, thereby transmitting the protection system optical transmission signal. The normality of the part can be confirmed. When a transmission error occurs in the 0-system optical transmission unit 1 operating as the active system, a switching command is externally input to the monitoring control unit 8.

When a switching command is input from the outside, the monitoring control unit 8 confirms whether or not the 1-system optical transmission unit 2 operating as the standby system is normal based on the signal level of the standby monitor signal S6. In some cases, the optical switch 5 generates a switching control signal S4 for connecting the input port to the output port A and causing the optical switch 4 to connect the input port to the output port B. As a result, switching between the active system and the standby system is performed.

In FIG. 1, since the reliability when transmitting a transmission signal from the network to the user equipment often becomes a problem, the optical concentrator 1 requires a route from the user equipment to the network. Although not shown, an optical receiver is naturally provided. At this time, it is possible to use one optical receiver by switching with an optical switch. However, since the optical switch is expensive, it is necessary to correspond to the 0-system optical transmitter 2 and the 1-system optical transmitter 2. It is preferable to provide 0-system and 1-system optical receiving units.

Further, the 0-system PD6 1 system PD7, but with <br/> the one that can also used by switching the optical switch, the optical switch is expensive as described above, the present embodiment In the form, each is provided exclusively.

[0030]

As described above, according to the first aspect of the present invention, in an optical concentrator in a PDS type optical communication system, an optical signal transmission system and a route from the optical signal transmission system to an optical star coupler. since duplicated only lower cost capital investment and other to enable the construction of PDS type optical communication system capable of providing reliable communication services, the health of the transmission system operating as a standby system Since the switching is performed after the confirmation, the reliability of the communication service can be reliably increased.

[003 1] According to the invention described in claim 2, the light switch
Since the switch is used, the monitoring means constituting the switching means can be configured at a low cost, and the cost increase can be minimized.

[Brief description of the drawings]

FIG. 1 is a configuration block diagram of an optical concentrator according to an embodiment of the present invention.

FIG. 2 is a configuration block diagram of a conventional PDS optical communication system.

[Description of Signs] 1 Optical concentrator 2 0-system optical transmitter 3 1-system optical transmitter 4 0-system optical switch 5 1-system optical switch 6 0-system photodiode (0-system PD) 7 1-system photodiode (1-system PD) 8 Monitoring control unit 21 User device 22 Optical transmission line 23 Optical star coupler

Claims (5)

[Claims] 1. An optical concentrator in which a large number of user devices are connected via an optical transmission line and an optical star coupler, respectively, wherein at least two sets of optical transmission systems for transmitting optical signals toward the optical star coupler are provided. An optical line concentrator, comprising switching means for switching an optical transmission line between each of the two sets of optical transmission systems and the optical star coupler from a working transmission line to a standby transmission line. . 2. The optical concentrator according to claim 1, wherein the switching unit monitors an operation state of a transmission system operating as a standby system, a switching command input from outside, and the monitoring unit. Control means for controlling the switching operation based on the output of the optical line concentrator. 3. The optical line concentrator according to claim 2, wherein the monitoring unit has an input port connected to an output port of the optical transmission system via an optical transmission line, and one of the two output ports. Are two optical switches connected to the optical star coupler via an optical transmission line, and one optical switch receives an input port and one output port in response to a control signal from the control means. The two optical switches are connected to each other to form a working system, and the other optical switch connects an input port and the other output port to form a standby system, and receives output light from the other output port of each of the two optical switches. An optical concentrator comprising two light receiving means. 4. A passive double-star optical communication system for connecting an optical concentrator and a number of user devices via an optical transmission line and an optical star coupler, wherein the optical concentrator comprises at least a duplicated optical transmission system. A method of switching between an active system and a standby system, wherein an optical transmission line between each of the optical star couplers and the optical star coupler is switched from an active transmission line to a standby transmission line. 5. The method for switching between the active system and the standby system according to claim 4, wherein an operation state of the transmission system operating as a standby system is monitored, and a switching command input from outside and a result of the monitoring are provided. Controlling the switching operation on the basis of
How to switch the standby system.