JP2001320392A - Vc path warning transfer system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a VC path warning transfer system, capable of transferring warning information. SOLUTION: VC path terminating parts 12 and 13 terminate a 0-system VC path of a route C section and 1-system VC path of a route D section for detecting a 0-system VC path signal and a 1-system VC path signal. A VC path warning switch transferring part 15 detects a warning signal from the 0-system VC path signal or the 1-system VC path signal and sends the detected signal to a warning inserting part 16. A VC path switch part 14 switch-connects the 0-system VC path and the 1-system VC path. The part 16 generates a VC path signal by received warning information and sends it to a branching part 17, which branches this VC path signal into two and sends them to a 0-system section and a 1-system section. VC path terminating parts 22 and 23 terminate the VC paths of the 0-system section and the 1-system section to detect the VC path signal. A VC path warning switch transferring part 25 sends the warning information detected from the VC path signal to a branching part 27 by the VC path signal. The part 27 sends the VC path signal to the 0-system VC path and to the 1-system VC path.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to the transfer of alarm information on a VC path of SDH.

[0002]

2. Description of the Related Art Conventionally, an SDH network has a plurality of ring SDHs.
It is configured by connecting networks. The ring SDH network is configured by connecting a plurality of SDH optical transmission devices in a ring shape by a bidirectional optical transmission line (referred to as a single section) including a clockwise optical transmission line and a counterclockwise optical transmission line. I have. Then, the SDH network is configured by connecting the ring SDH networks by a duplex optical transmission line (called a duplex section).

A VC path of a ring SDH network is a ring SDH network.
Duplex V by VC paths accommodated in each of the clockwise optical transmission line and the counterclockwise optical transmission line of the single section of the H network
It has a C path. The VC path between the ring SDH networks is configured to have VC paths respectively accommodated in the 0-system section and the 1-system section of the duplex section. The SDH optical transmission device temporarily terminates the duplex VC path accommodated in the simplex section of the ring SDH network,
Then, it connects to the VC path accommodated in the duplex section between the ring SDH networks, and transfers VC signals between the ring SDH networks.

[0004]

SUMMARY OF THE INVENTION Such a conventional SD
In the H network, since the duplicated VC path of the ring SDH network is temporarily terminated, the alarm information transferred by the duplicated VC path cannot be transferred to the VC path accommodated in the duplicated section. have.

[0005] An object of the present invention is to solve such a conventional problem and to provide a VC path alarm transfer system capable of transferring alarm information.

[0006]

According to the VC path alarm transfer method of the present invention, a first VC (virtual container) path is terminated and a first VC path signal is detected, and a second VC path is terminated and a second VC path signal is detected. And a VC path terminating means for selecting and switching any one of the first VC path and the second VC path to connect to the third VC path.
C path switching connection means, the first VC path and the second VC path from the first VC path signal and the second VC path signal.
A VC alarm which recognizes whether any of the paths is an operating VC path, detects alarm information from a VC path signal of the VC path recognized as operating, and transmits the alarm information to the third VC path. And transmitting means.

[0007] The VC path alarm transfer system of the present invention comprises:
A first section (transmission line), a second section, and a duplex section configured by duplexing a 0-system section and a 1-system section; and a 0-system VC accommodated in the first section A double VC path configured by duplexing a path and a first system VC path accommodated in the second section, and a second VC path accommodated in the zero system section and the first system section of the duplex section. 3VC path,
First VC path terminating means for terminating the 0-system VC path and detecting the 0-system VC path signal, and terminating the 1-system VC path and detecting the 1-system VC path signal; and the 0-system VC path and the 1-system VC path signal First VC path switching connection means for selecting and switching any one of the VC paths and connecting to the third VC path, and the 0-system VC path from the 0-system VC path signal and the 1-system VC path signal. It recognizes which one of the 1-system VC paths is the operating VC path, detects alarm information from the VC path signal of the VC path recognized as operating, and checks the 0-system VC path and the 1-system VC path. V VC path so as to select any one of the
A first VC path alarm switching control means for controlling the C path switching connection means, a third VC path signal generated by inserting the alarm information into a path overhead, and a third VC path signal accommodated in the third VC path; And a first VC alarm transmitting means for transmitting in parallel to the 0-system section and the 1-system section.

Further, in the VC path alarm transfer system according to the present invention, the third VC path accommodated in the 0-system section of the duplex section is terminated, a VC path signal is detected, and the VC section signal is transmitted to the redundant section. Second VC path terminating means for terminating the third VC path accommodated in the first system section and detecting a VC path signal, and accommodated in the third VC path accommodated in the zero system section and the first system section A second VC path switching connection means for selecting and switching any one of the third VC paths and connecting to the duplicated VC path, and any one of the 0-system section and the 1-system section Is an operation section, alarm information is detected from a VC path signal of a VC path accommodated in the operation section, and the second V Second controlling the path switching connection means
VC path alarm switching control means, a fourth VC path signal is generated by inserting the alarm information into the path overhead, and the fourth VC path signal is transmitted to the 0-system VC path accommodated in the first section and the fourth VC path signal. And a second VC alarm transmitting means for transmitting the data in parallel to the first system VC path accommodated in the two sections.

Further, the VC path alarm transfer system of the present invention
It is characterized by having a section configured by duplicating the first section and the second section.

Further, the VC path alarm transfer system of the present invention provides a plurality of SDHs in a single section comprising a bidirectional optical transmission line formed by a pair of a clockwise transmission line and a counterclockwise transmission line.
(Synchronous Digital Hier
archy) It has a plurality of ring SDH networks constituted by connecting optical transmission devices in a ring shape, and is duplexed by a system 0 section comprising a bidirectional optical transmission line and a system 1 section comprising a bidirectional optical transmission line. An SDH network configured by connecting the ring SDH networks with a configured duplex section, a 0-system VC path is set in a clockwise transmission path of the simplex section, 1 on the counterclockwise transmission line
VC path setting means for setting a system VC path to set a double VC path in the simplex section and setting a third VC path in the zero system section and the first system section of the double section. A simplex section terminating means for terminating the simplex section, and terminating the 0-system VC path set in the simplex section by 0
A system VC path signal is detected, and the system VC path set in the simplex section is terminated and the system VC path is terminated.
First VC path termination means for detecting a path signal; first VC path switching connection means for selecting and switching any one of the 0-system VC path and the 1-system VC path to connect to the third VC path; The 0-system VC path signal and the 1-system V
From the C path signal, it is recognized whether one of the 0-system VC path and the 1-system VC path is the operating VC path, and alarm information is detected from the VC path signal of the VC path recognized as operating. And a first VC path alarm switching control means for controlling the VC path switching connection means so as to select and switch between any one of the 0-system VC path and the 1-system VC path, and the first VC path The alarm information detected by the alarm switching control means is inserted into the path overhead to generate a third VC path signal, and the third VC path signal is paralleled to the 0-system section and the 1-system section in which the third VC path is set. And a first VC alarm transmitting means for transmitting.

Further, the VC path alarm transfer system of the present invention
Duplex section terminating means for terminating the duplex section; terminating the third VC path set in the 0-system section of the duplex section to detect a VC path signal; A second VC path terminating means for terminating the third VC path set in the first system section and detecting a VC path signal; and setting the third VC path and the first system section set in the zero system section. Second VC path switching connection means for selecting and switching any one of the third VC paths to be connected to the duplicated VC path, and any one of the zero-system section and the first-system section. Is recognized as an operation section, alarm information is detected from the VC path signal of the VC path set in the operation section, and A second VC path alarm switching control unit for controlling the 2VC path switching connection unit; and inserting the alarm information detected by the second VC path alarm switching control unit into a path overhead to generate a fourth VC path signal. The signal is applied to the 0-system V set in the single section.
And a second VC alarm transmitting means for transmitting the C-path and the first-system VC path in parallel.

Further, the VC path alarm transfer system according to the present invention provides a system 0 section comprising a bidirectional optical transmission line formed by a pair of a clockwise transmission line and a counterclockwise transmission line, a clockwise transmission line and a counterclockwise transmission line. A ring SDH network configured by connecting a plurality of SDH optical transmission devices in a ring by a double section configured to be duplexed with a system section including a bidirectional optical transmission path formed by a pair with a path. A VC path setting means for setting a 0-system VC path in the 0-system section and a 1-system VC path in the 1-system section, wherein the SDH optical transmission apparatus inputs the SDH optical transmission apparatus. Terminate the 0-system section (input 0-system section)
A section terminating means for terminating the 1-system section (input 1-system section) input to the SDH optical transmission device, and a 0-system VC set in the input 0-system section
A VC path terminating means for terminating the path and detecting the 0-system VC path signal, terminating the 1-system VC path set in the input 1-system section, and detecting the 1-system VC path signal; One of the 0-system VC path set in the section and the 1-system VC path set in the input 1-system section is selected and switched, and the 0-bit output from the SDH optical transmission device is selected. 0-system VC set in the system section (output 0 system section)
Path and the 1st system V set in the 1st system section (output 1st system section) output from the SDH optical transmission device
A VC path switching connection means for connecting to both the C path and the 0 system VC path signal and the input 1 set in the input 0 system section based on the 0 system VC path signal and the 1 system VC path signal. Recognizing whether any of the first-system VC paths set in the system section is an operating VC path, detecting alarm information from a VC path signal of the VC path recognized as operating, and VC path alarm switching control means for controlling switching connection of the VC path switching connection means, and alarm information detected by the VC path alarm switching control means are inserted into a path overhead to generate a VC path signal, and the VC path signal is generated. For transmitting in parallel to both the 0-system VC path set in the output 0-system section and the 1-system VC path set in the output 1-system section
And a warning transmitting means.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram showing an SD according to a first embodiment of the present invention.
FIG. 2 is a block diagram of an SDH optical transmission device constituting a node of the SDH network, FIG. 2A is a block diagram of a transmission side SDH transmission device, and FIG. ,
FIG. 2 is a block diagram of a receiving-side SDH transmission device.

Referring to FIG. 1, SDH (Synchronous Digital) according to a first embodiment of the present invention.
The Hierarchy network includes a plurality of ring SDH networks 1 and 2.

Each of the plurality of ring SDH networks 1 and 2
The DH optical transmission device 100 is a node, and a plurality of SDH optical transmission devices 100 are connected in a ring shape.

In each of the ring SDH networks 1 and 2, S
Between each of the DH optical transmission devices 100 (100-1 and 100
-2, 100-3, and 100-4 and 100-5, 100-6, 100-7, and 100-8) are two-way light formed by a pair of a clockwise transmission line and a counterclockwise transmission line. It has a single section 400 composed of a transmission line.

Each of the ring SDH networks 1 and 2 has a duplex VC path in which a 0-system VC path is set in a clockwise transmission path and a 1-system VC path is set in a counterclockwise transmission path. Be composed.

Between the plurality of ring SDH networks 1 and 2, there are duplicated 2 sections of a 0-system section 501 composed of a bidirectional optical transmission path and a 1-system section 502 composed of a bidirectional optical transmission path.
It has a weighting section 500.

The SDH optical transmission device 100 has a transmission function (hereinafter referred to as a transmission-side SDH optical transmission device 100S) shown in FIG.
) And a receiving function shown in FIG. 2B (hereinafter, referred to as a receiving-side SDH optical transmission device 100R). For convenience of explanation, the transmitting-side SDH transmission device 100
S and the receiving-side SDH optical transmission device 100R in FIG.
2 and FIG. 2B. For convenience of explanation, as shown in FIG. 1, a duplex section between the ring SDH networks 1 and 2 is called a route A, and a duplex section between the adjacent SDH optical transmission apparatuses 100 is called a route C. And route D.

Referring to FIG. 2A, the transmission-side SDH optical transmission apparatus 100S includes section terminators 10 and 11,
C path terminating units 12 and 13, VC path switching unit 14,
It is configured to include a C-path alarm switch / transfer unit 15, an alarm insertion unit 16, and a branch unit 17.

The section terminating section 10 terminates the single section of the route C.

The VC path terminating unit 12 terminates the 0-system VC path included in the single section of the route C and detects the 0-system VC path signal. Here, the VC path signal is VC,
That is, the path signal is composed of a path overhead (POH) included in the virtual container.

The section termination section 11 terminates the single section of the route D.

The VC path terminating section 13 terminates the first system VC path included in the single section of the route D and detects the first system VC path signal.

The VC path switching unit 14 includes a 0-system VC path and a 1-system VC path.
Any one of the system VC paths is selected and switched and connected.

The VC path alarm switch / transfer unit 15 determines the 0-system VC path and the 1-system VC path from the 0-system VC path signal terminated by the VC path termination unit 12 and the 1-system VC path signal terminated by the VC path termination unit 13. It recognizes which of the paths is the active VC path, detects alarm information from the VC path signal of the active VC path, and switches between the 0 system VC path and the 1 system VC path. The VC path switching unit 14 is controlled so as to be connected.

The alarm insertion section 16 inserts the alarm information detected by the VC path alarm switch / transfer section 15 into the path overhead, generates a VC path signal, and sends it to the branching section 17.

The branching unit 17 branches the VC path signal containing the alarm information from the alarm inserting unit 16 into two,
Each of the C-path signals is transmitted in parallel to the 0-system section 501S and the 1-system section 502S of the duplex section 500 (route A) using the SDH signal.

Referring to FIG. 2B, the receiving-side SDH optical transmission device 100R includes section terminators 20 and 21,
C path terminating units 22 and 23, VC path switching unit 24,
It is configured to include a C-path alarm switch / transfer unit 25, an alarm insertion unit 26, and a branch unit 27.

The section termination section 20 terminates the 0-system section 501R of the duplex section 500.

The VC path terminating unit 22 includes a 0-system section 5
The VC path contained in 01R is terminated and a VC path signal is detected.

The section termination section 21 terminates the first system section 502R of the duplex section 500.

The VC path terminating unit 23 includes the first system section 5
The VC path contained in the 02R is terminated to detect a VC path signal.

The VC path switching section 24 has a
VC path housed in 01R and 1st system section 50
The connection is switched to one of the VC paths accommodated in the 2R.

The VC path alarm switch / transfer unit 25 recognizes which of the 0-system section 501R and the 1-system section 502R is the working system section, and recognizes the VC path of the VC path accommodated in the working system section. Alarm information is detected from the path signal.

The alarm insertion section 26 inserts the alarm information detected by the VC path alarm switch / transfer section 25 into the path overhead, generates a VC path signal, and sends it to the branching section 27.

The branching section 27 receives the VC from the alarm inserting section 16
The path signal is branched into two, and each of the two branched VC path signals is converted into a single section of the route C and a route D by the SDH signal.
In parallel with the single section. That is, the branching unit 27 transfers each of the VC path signals including the alarm information, which has been branched into two, to the 0-system VC path and the 1-system VC path of the duplicated VC path.

Next, the operation of the first embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 3 is a diagram for explaining a logical VC path at the time of alarm information transfer according to the first embodiment.

Referring to FIG. 1, FIG. 2 and FIG.
From the node 8 (SDH optical transmission device 100-7) of the DH network 2 to the node 1 (SDH optical transmission device 10) of the ring SDH network 1.
The operation of transferring the alarm information to 0-1) will be described.

In FIG. 3, between the nodes 7 and 5 of the ring SDH network 2, a 0-system VC path c is set on the counterclockwise transmission line, and a 1-system VC path c is set on the clockwise transmission line. , A duplicated VC path c is set. Further, between the node 3 and the node 1 of the ring SDH network 1, the 0-system VC path a is set on the counterclockwise transmission path, the 1-system VC path a is set on the clockwise transmission path, and the duplex VC path is set. The path a is set. Then, the node 5 of the ring SDH network 2
A single VC path b is set in a duplex section between the (SDH optical transmission device 100-5) and the node 3 (SDH optical transmission device 100-3) of the ring SDH network 1.

When a fault occurs in a single section between the node 8 and the node 7, the node 8 generates alarm information due to the fault, generates a VC path signal including the alarm information, and generates the VC path signal. Is inserted into the 0-system VC path c.
Since this VC path signal does not have the node 8 on the 1-system VC path c, the VC path signal including the alarm information is not inserted into the 1-system VC path c.

SDH optical transmission device 100 in node 5
-5 The sender SDH optical transmission device 100S, the first, end section termination unit 10 terminates the singularization section of route C _2, section termination unit 11, a simplex section of route D ₂ I do.

The VC path terminating unit 12 terminates the 0-system VC path c included in the single section of the route C ₂ and
The C path signal is detected. At this time, the 0-system VC path signal includes the alarm information generated by the node 8.

[0046] VC path termination unit 13, route 1 system terminates the 1-system VC paths in the simplex section of D ₂ VC
Detect the path signal. At this time, the 1-system VC path signal does not include the alarm information generated by the node 8.

The VC path alarm switch / transfer section 15 receives the 0-system VC path signal terminated by the VC path terminating section 12 and the 1-system VC path signal terminated by the VC path terminating section 13, and receives the 0-system VC path signal. The alarm information generated by the node 8 is detected from one of the first and the first system VC path signals (here, the zero system VC path signal), and the alarm information is sent to the alarm insertion unit 16.

At this time, the VC path alarm switching transfer section 15
Can detect alarm information from the 0-system VC path signal, while
Recognizing that the alarm information cannot be detected from the 1-system VC path signal, it notifies the VC path switching unit 14 of a switching control instruction to switch and connect the 0-system VC path c to the 1-system VC path c.

The VC path switching unit 14 issues a faulty 0-system VC
The path c is switched to a normal 1-system VC path c for connection.

The alarm insertion section 16 inserts the alarm information notified from the VC path alarm switching / transfer section 15 into the path overhead to generate a VC path signal, and sends this VC path signal to the branching section 17.

The branching unit 17 branches the VC path signal containing the alarm information from the alarm inserting unit 16 into two,
Each of the C-path signals is transmitted in parallel to the 0-system section 501S and the 1-system section 502S of the duplex section 500 (route A) using the SDH signal. That is, the branching unit 17 includes the zero-system section 50 of the duplex section 500.
The VC path signal including the alarm information is transferred to the VC path b set in each of the 1S and the 1-system section 502S.

SDH optical transmission device 100 in node 3
In the receiving side SDH optical transmission device 100R of -3, the section terminator 20 terminates the 0-system section 501S of the duplex section 500, and the section terminator 21 terminates the 1-system section 502S of the duplex section 500. I do.

The VC path terminating unit 22 includes the 0-system section 5
The VC path b included in 01S is terminated and a VC path signal is detected.

The VC path terminating unit 23 includes the first system section 5
The VC path b included in 02S is terminated and a VC path signal is detected.

The VC path alarm switching / transfer unit 25 recognizes which of the 0-system section 501S and the 1-system section 502S is the active system section, and determines the VC path of the VC path b included in the active system section. Alarm information is detected from the signal. Here, assuming that the 0-system section 501S is the active system section, the VC path alarm switching and transferring unit 25 detects alarm information from the VC path signal of the VC path b included in the 0-system section 501S.

The VC path switching section 24 connects the VC path b included in the 0-system section 501S, which is the active section.

The alarm insertion unit 26 inserts the alarm information detected by the VC path alarm switching and transferring unit 25 into the path overhead, generates a VC path signal, and sends it to the branching unit 27.

The branching unit 27 receives the VC from the alarm inserting unit 16
Path signal 2 branches, each of 2 branched VC path signal, transmitted by SDH signals, parallel to the simplex section and the singularization section of catalog D ₁ of the route C _1. That is, the branching unit 27 includes the VC that includes the alarm information that has been branched into two.
Each of the path signals is transferred to the node 1 via the duplicated VC path 0-system VC path a and the 1-system VC path a.

As a result, the alarm information of the VC path relaying the duplex section can be transferred between the ring SDH networks, and the effect that the end node can detect the VC path alarm can be obtained. Can be As a result, when the ring SDH networks are connected by the duplex section, an effect is obtained that a plurality of terminal VC paths between terminal nodes over the network can be managed collectively.

Next, a second embodiment of the present invention will be described.

FIG. 4 is a configuration diagram of a ring SDH network according to the second embodiment of the present invention, and FIG. 5 is a diagram illustrating a logical VC path at the time of alarm information transfer according to the second embodiment.

Referring to FIG. 4, the ring SDH network according to the second embodiment of the present invention comprises an SDH optical transmission device 100S and a receiving SDH optical transmission device 100R shown in FIG. The transmission device 100 is a node, and a plurality of SDH optical transmission devices 100-1, 100-2, 100-
3, 100-4 are connected in a ring shape.

Between each of the SDH optical transmission devices 100, a double section 500-1 constituted by duplexing a system 0 section comprising a bidirectional optical transmission line and a system 1 section comprising a bidirectional optical transmission line. , 500-2, 500-3, 50
0-4 are connected.

Here, the SDH optical transmission device 1 shown in FIG.
The route A, the route C, and the route D of 00-1 are represented by S in FIG.
These correspond to the route A, the route C, and the route D of the DH optical transmission device 100.

Referring to FIG. 5, the VC paths of the ring SDH network have duplicate sections 500-1, 500-2, and 50.
Duplicate VC paths 600-1, 600-2, which are composed of a 0-system VC path set in the 0-system section of 0-3 and 500-4 and a 1-system VC path set in the 1-system section.
600-3 and 600-4.

The operation of the second embodiment of the present invention
Will be described as an example.

The section termination section 10 of the SDH optical transmission apparatus 100-1 terminates the 0-system section of the duplex section 500-4, and the section termination section 11 terminates the 1-system section of the duplex section 500-4. Terminate.

The VC path terminating section 12 terminates the 0-system VC path set in the 0-system section and detects the 0-system VC path signal, and the VC path terminating section 13 sets the 1-system section to the 1-system section. The system VC path is terminated and a system VC path signal is detected.

The VC path alarm switch / transfer unit 15 is provided with a 0-system VC
From the path signal and the 1-system VC path signal, the 0-system VC path and 1
It recognizes which of the system VC paths is the operating VC path, detects alarm information from the VC path signal of the VC path recognized as operating, and switches to the VC path switching connection unit 14 for switching connection. Instruct control.

The VC path switching connection section 14 selects and switches one of the 0-system VC path and the 1-system VC path in accordance with an instruction from the VC path alarm switching transfer section 15.

The alarm insertion unit 16 inserts the alarm information detected by the VC path alarm switch / transfer unit 15 into the path overhead, generates a VC path signal, and sends it to the branching unit 17.

The branching unit 17 branches the VC path signal containing the alarm information from the alarm insertion unit 16 into two,
Each of the C-path signals is transmitted in parallel to the 0-system section and the 1-system section of the duplex section 500-1 using the SDH signal. That is, the branching unit 17 converts each of the two branched VC path signals including the alarm information into a double VC
0 system VC path and 1 system V set in path 500-1
Transfer to C path.

[0073]

As described above, according to the present invention, in a configuration in which a plurality of terminal VC paths are relayed, once terminated V
Since the configuration is such that the alarm information of the C path is relayed to the VC path to be relayed, there is an effect that the alarm information can be transferred between the terminal VC paths. Also, there is an effect that a plurality of terminal VC paths between terminal nodes can be managed collectively between VC paths.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of an SDH network according to a first embodiment of the present invention.

FIG. 2 is a block diagram of an SDH optical transmission device constituting a node of the SDH network.

FIG. 3 is a logic VC at the time of alarm information transfer according to the first embodiment;
It is a figure explaining a path.

FIG. 4 is a configuration diagram of a ring SDH network according to a second embodiment of the present invention.

FIG. 5 shows a logical VC at the time of alarm information transfer according to the second embodiment.
It is a figure explaining a path.

[Explanation of symbols]

 1, 2 ring SDH network 10, 11, 20, 21 Section termination section 12, 13, 22, 23 VC path termination section 14 VC path switching section 15 VC path alarm switching / transfer section 16 Alarm insertion section 17 Branch section 100 SDH optical transmission Apparatus 400 Single section 500 Double section

Claims (7)

[Claims] 1. VC path terminating means for terminating a first VC (virtual container) path and detecting a first VC path signal, and terminating a second VC path and detecting a second VC path signal; and the first VC path and the first VC path signal. A VC path switching connection means for selecting and switching any one of the 2 VC paths to connect to the third VC path, and the first VC path and the second VC path based on the first VC path signal and the second VC path signal.
A VC that recognizes which of the C paths is the operating VC path, detects alarm information from the VC path signal of the VC path recognized as operating, and transmits the alarm information to the third VC path. And VC transmission means. 2. A first section (transmission path), a second section, and a duplex section configured by duplexing a 0-system section and a 1-system section, and are accommodated in the first section. A redundant VC path configured by duplicating a zero-system VC path that is located in the second section and a first-system VC path that is accommodated in the second section;
Third VC housed in system section and system section
A first VC path terminating means for terminating the 0-system VC path and detecting the 0-system VC path signal, and terminating the 1-system VC path and detecting the 1-system VC path signal; A first path connected to the third VC path by selecting and switching one of the path and the first system VC path.
C path switching connection means, the 0-system VC path signal and the 1
From the system VC path signal, the 0 system VC path and the 1 system VC path are used.
Of the VC path recognized as being in operation, alarm information is detected from the VC path signal of the VC path recognized as being in operation, and the 0-system VC path and the 1
A first VC which controls the VC path switching connection means so as to select any one of the system VC paths and switch and connect the selected VC path.
Path alarm switching control means for generating a third VC path signal by inserting the alarm information into a path overhead, and converting the third VC path signal to the 0-system section and the 1-system section in which the third VC path is accommodated; To send in parallel to the first
And VC alarm transmission means. 3. The third VC path contained in the 0-system section of the duplex section is terminated to detect a VC path signal, and the third VC path contained in the 1-system section of the duplex section is detected. Terminate 3VC path and VC
A second VC path terminating means for detecting a path signal, the third VC path housed in the 0-system section, and the 1st VC path;
Second VC path switching connection means for selecting and switching any one of the third VC paths accommodated in the system section and connecting to the duplicated VC path, the 0 system section and the 1 system section And the alarm section detects alarm information from the VC path signal of the VC path accommodated in the operation section and controls the second VC path switching connection means. 2VC path alarm switching control means, and generating the fourth VC path signal by inserting the alarm information into the path overhead, and transmitting the fourth VC path signal to the 0-system VC path accommodated in the first section and the fourth VC path signal. 3. A VC path alarm relay according to claim 2, further comprising: a second VC alarm transmission unit for transmitting the VC path alarm in parallel with the first system VC path accommodated in the two sections. Method. 4. The VC according to claim 2, further comprising a section configured by duplicating the first section and the second section.
Path alarm transfer method. 5. A plurality of SDHs (Synchronous Digital) in a single section comprising a bidirectional optical transmission line formed by a pair of a clockwise transmission line and a counterclockwise transmission line.
Hierarchy) It has a plurality of ring SDH networks formed by connecting optical transmission devices in a ring shape, and has a system 0 section composed of bidirectional optical transmission paths and a section 1 composed of bidirectional optical transmission paths.
An SDH network configured by connecting the ring SDH networks with a duplex section configured to be redundant with a system section, and a 0-system VC path is set in a clockwise transmission line of the simplex section Then, by setting a 1-system VC path in the counterclockwise transmission line of the single-section section, a double-VC path is set in the single-section section, and a zero-system section of the double-section section is set. VC path setting means for setting a third VC path to the 1-system section; unified section terminating means for terminating the unified section; and terminating the 0-system VC path set to the unified section. A first VC path terminating means for detecting a 0-system VC path signal, terminating the 1-system VC path signal set in the single section, and detecting a 1-system VC path signal; A first VC path switching connection means for selecting and switching any one of the first VC path and the first VC path to connect to the third VC path, and the first VC path signal and the first VC path signal. It recognizes which of the system VC path and the system VC path is the operating VC path, detects alarm information from the VC path signal of the VC path recognized as operating, and detects the 0 system VC path. A first VC path alarm switching control means for controlling the VC path switching connection means so as to select and connect any one of a path and the first system VC path, and the first VC path alarm switching control means detects The third VC path signal is generated by inserting the alarm information into the path overhead, and the third VC path signal is transmitted in parallel to the system 0 section and the system 1 section in which the third VC path is set. VC path alarm transfer method and having a 1VC warning transmitting means. 6. A duplex section terminating means for terminating the duplicate section, and terminating the third VC path set in the zero-system section of the duplicate section by V
A second VC path terminating means for detecting a C path signal, terminating the third VC path set in the first section of the duplex section, and detecting a VC path signal;
The third VC path set in the zero system section and the third VC set in the first system section
A second VC path switching connection means for selecting and switching any one of the paths and connecting to the duplicated VC path, and one of the 0-system section and the 1-system section being an operation section. A second VC path alarm switching control means for recognizing the presence of the alarm, detecting alarm information from a VC path signal of the VC path set in the operation section, and controlling the second VC path switching connection means; The alarm information detected by the path alarm switching control means is inserted into the path overhead to generate a fourth VC path signal,
6. The second VC alarm transmitting means for transmitting the fourth VC path signal to the 0-system VC path and the 1-system VC path set in the single section in parallel with each other. VC path alarm transfer method. 7. A system 0 section comprising a bidirectional optical transmission line formed by a pair of a clockwise transmission line and a counterclockwise transmission line, and a bidirectional optical transmission line formed by a pair of a clockwise transmission line and a counterclockwise transmission line. A ring SDH network configured by connecting a plurality of SDH optical transmission devices in a ring by a double section configured to be duplexed with a first system section comprising a zero system VC path is provided in the zero system section. And a VC path setting means for setting a 1-system VC path in the 1-system section, wherein the SDH optical transmission apparatus is configured to input the 0-system section (input 0-system section) to be input to the SDH optical transmission apparatus.
Section terminating means for terminating the first system section (input 1 system section) input to the SDH optical transmission apparatus, and terminating the 0 system VC path set in the input 0 system section to terminate the 0 system VC. VC path terminating means for detecting a path signal, terminating the 1-system VC path set in the input 1-system section, and detecting a 1-system VC path signal; Any one of the 0-system VC path and the 1-system VC path set in the input 1-system section is selected and switched, and the 0-system output from the SDH optical transmission device is switched.
Connection is made to both the 0-system VC path set in the system section (output 0 system section) and the 1-system VC path set in the 1 system section (output 1 system section) output from the SDH optical transmission device. The VC path switching connection means for performing the switching and the 0 system VC path signal and the 1 system VC path signal,
It recognizes whether one of the system VC path and the first system VC path set in the input first system section is the operation VC path, and issues an alarm from the VC path signal of the VC path recognized as operation. VC path alarm switching control means for detecting information and controlling the switching connection of the VC path switching connection means, and inserting the VC path signal by inserting the alarm information detected by the VC path alarm switching control means into a path overhead. VC alarm transmitting means for generating and transmitting the VC path signal in parallel to both the 0-system VC path set in the output 0 system section and the 1-system VC path set in the output 1 system section; A VC path alarm transfer method, comprising: