JP2001230732A - Wavelength multiplex system monitoring method and device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system and a method for judging the correspondence relation of auxiliary signals and main signals in a wavelength multiplex transmission system. SOLUTION: The main signals and the auxiliary signals are separated from received composite signals and an identifier IDC read from the main signals and the identifier IDA read from the component of the auxiliary signals relating to the main signals are compared (step 834). In the case that the identifiers do not match, it is judged that the correspondence relation of the main signals and the auxiliary signals is lost (step 836).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the field of optical networks, and more particularly, to a method and a system for determining a correspondence between an auxiliary signal and a main signal in a wavelength division multiplexing transmission system.

[0002]

2. Description of the Related Art As the use of optical networks spreads,
There is an increasing demand for systems and methods for detecting faults in multi-wavelength optical transmission systems. When a failure occurs in an optical network, a main signal or a channel of a transmission signal may be affected. Such a failure of the main signal causes a plurality of alarms to be generated in a network component device located downstream of the failure, resulting in preventing the location of the failure from being identified. In order to avoid such a situation, forward failure notification information for notifying a downstream network device of signal destruction due to an upstream failure is transmitted. With such failure notification information, the network monitoring device can appropriately separate the failure itself from devices and span segments of the failed network.

[0003]

However, from the viewpoint of efficiency, the known method of transmitting failure notification information has not always been satisfactory.

In the conventional method, the network component that first detects a failure inserts failure notification information into an overhead portion of each affected main signal. SDH and SO
In the NET system, a network device having a path connection function converts an input main signal from an optical signal to an electric signal. The overhead portion of the main signal is accessible because the signal is an electric signal, and failure notification information can be inserted into the overhead portion of the signal. However, in networks based on wavelength division multiplexing transmission,
Some network components, such as a wavelength multiplexer / demultiplexer and an optical cross connect, realize a signal connection function that does not perform conversion into an electric signal. Therefore, there is essentially no means for accessing the main signal overhead section for inserting the failure notification information. Therefore, in a system including such a network configuration device, it is more difficult to isolate a failure point.

In another conventional method, an auxiliary signal is wavelength division multiplexed and transmitted together with a main signal. In addition to the network component that does not convert the main signal into an electrical signal, the failure notification information is inserted into the auxiliary signal also in the network component that converts the main signal into an electrical signal. However, the original correspondence between the auxiliary signal and the main signal may be lost, and the failure notification information of the auxiliary signal may not match the corresponding main signal.

[0006] Although the above-mentioned method has improved the prior art, the demand for more efficient and better technology is only increasing in the field of optical networks.
Therefore, there is a need to provide a system and method for determining the correspondence between an auxiliary signal and a main signal in a wavelength division multiplexing transmission system.

[0007]

SUMMARY OF THE INVENTION In accordance with the present invention, an auxiliary signal and a main signal in a wavelength division multiplex transmission system are provided which substantially eliminate or reduce disadvantages and problems of previously developed systems and methods. And a method for determining the correspondence between the two.

According to one embodiment of the present invention, a network configuration apparatus for a wavelength division multiplexing transmission system is disclosed. The network configuration device includes a receiving unit and a correspondence determining unit. The receiving means includes a plurality of main signals each having an identifier and different wavelengths from each other, and an auxiliary signal including a component having an identifier associated with each corresponding main signal (hereinafter, referred to as a corresponding identifier). Receiving the combined signal. The correspondence relationship determination means is connected to the reception means, compares the identifier from the main signal with the correspondence identifier from the component corresponding to the main signal, and determines whether the identifier from the main signal and the correspondence identifier from the component are equal. If they do not match, it is determined that the correspondence has been lost.

According to another embodiment of the present invention, a method for determining correspondence between signals in an optical transmission network is disclosed. A composite signal is received. The composite signal comprises a plurality of main signals, each having an identifier and different wavelengths, and an auxiliary signal for each corresponding main signal having a component having a corresponding identifier. The identifier from the main signal is compared with the corresponding identifier from the component corresponding to the main signal. If the identifier from the main signal does not match the corresponding identifier from the component, it is determined that the correspondence has been lost.

According to another embodiment of the present invention, a system for detecting a state in which a correspondence has been lost by a computer is disclosed. The system also includes a computer program for the computer. The computer program corresponds to the identifier received from one of the plurality of main signals having different frequencies included in the synthesized signal and the main signal in the auxiliary signal included in the synthesized signal. And the corresponding identifier received from the corresponding component. If the identifier from the main signal does not match the corresponding identifier from the component, the computer program determines that the correspondence has been lost.

According to another embodiment of the present invention, a wavelength division multiplex transmission system is disclosed. The system includes a plurality of network components connected to each other by an optical transmission medium. The auxiliary signal generation device is connected to one of the plurality of network components and generates an auxiliary signal. The auxiliary signal has a component corresponding to each of a plurality of main signals each having an identifier, and each component includes a corresponding identifier. The first network configuration device combines a plurality of main signals and auxiliary signals having different frequencies,
The signal is transmitted to the optical transmission medium as one combined signal. The second network configuration device receives a composite signal including a plurality of main signals and an auxiliary signal including a plurality of components corresponding to the plurality of main signals, and outputs an identifier included in the main signal and a component corresponding to the identifier. It is determined whether the corresponding component corresponds to the main signal based on the correspondence identifier.

According to the present invention, there is obtained a technical effect that a method and a system for transmitting auxiliary information for a main signal in an optical network can be improved. In particular, a particular identifier corresponding to a particular main signal is transmitted as a component of the auxiliary signal. By using this specific identifier, it is possible to check whether the information included in the auxiliary signal matches the corresponding main signal. Therefore, according to the present invention, it is possible to effectively detect a location where a signal has failed in an optical network.

[0013]

FIG. 1 is a block diagram showing an embodiment of an optical communication network system 100 according to the present invention. In the system 100, a composite signal generated by performing wavelength division multiplexing of an auxiliary signal on a main signal is transmitted between network components. The auxiliary signal carries failure notification information and other information about the main signal. In each network component, the auxiliary signal is modified to reflect a change in the main signal.

The system 100 inserts failure notification information into an auxiliary signal that is wavelength division multiplexed with the main signal and transmitted together. The failure notification information can be inserted into the auxiliary signal by not only the network component that converts the main signal into the electric signal but also the network component that does not convert the main signal into the electric signal. However, the correspondence between the auxiliary signal and the main signal is lost due to malfunctioning software or hardware, and the failure notification information and other related information included in the auxiliary signal do not match the corresponding main signal. Sometimes. In order to detect such a problem, the system 100
A unique identifier (hereinafter, referred to as a specific identifier) different from the others is inserted into the auxiliary signal and the main signal, and it is determined whether or not the correspondence between the two has been lost.

As shown in FIG. 1, the system 100 includes a plurality of network components connected to each other by an optical transmission medium. In the present embodiment, as a network configuration device, a wavelength multiplexing device (WDM) 102, line amplifiers (LA) 104a-f, wavelength add / drop multiplexer (WADM) 1
06, 108, a regenerative repeater (RGN) 110, an optical cross connect (OXC) 112, and a wavelength separation device (W
DM) 116, 118. Also, other suitable combinations of network components can be used. Signals may pass between LA, RGN, WADM, OXC and other suitable network components any number of times. The system 100 is a multi-wavelength optical transmission system in which each of a main signal and an auxiliary signal is transmitted at a different wavelength.

[0016] Client mapper
The signal transmitters such as (CM) 130a-c
a-c are provided. In the system 100, three main signals 120a-c are used. However, any number of main signals can be multiplexed into one combined signal. The signal transmitter may be part of a network configuration device,
Further, it may be separated from the network configuration device. Each client mapper 130a-c generates a main signal by inserting a specific identifier corresponding to the main signal 120a-c into an overhead portion of the corresponding client signal 120a-c. Here, “each” refers to each of at least one subset element of the items to be identified. For example, the client mapper 130a inserts a specific identifier corresponding to the main signal 120a into an overhead part of the main signal 120a.

Each auxiliary signal generator (ASG) 132a-f
Generates an auxiliary signal including a channel-specific component corresponding to each main signal channel. Each channel-specific component includes a specific identifier corresponding to the main signal. ASG
132a-f are part of the network configuration device,
Alternatively, they are provided separately from them. The channel-specific component also includes other attributes that describe the main signal corresponding to that component, such as wavelength and fault notification information. For example, the auxiliary signal 122a includes a wavelength and a specific identifier of each of the main signals 120a-c, and failure notification information of the main signal having a failure. The failure notification information is, for example, forward failure notification information that prompts a downstream network component to be alerted to a failure that has occurred upstream. The failure notification information can also be inserted into the main signal by a network component that can access the overhead section of the main signal. Other suitable attributes include, for example, notification information regarding the type of client signal, reverse failure notification information, signal line information for an automatic protection switch, mounted or unmounted notification information, or a data communication channel. It is.

In the network configuration device capable of accessing the identifier, a specific identifier is compared with each main signal and a specific identifier from a component unique to each channel corresponding to the main signal channel, and the main signal and the auxiliary signal are compared. It is determined whether the correspondence is maintained or the correspondence is lost. This processing is performed, for example, by comparing a specific identifier of a main signal received at a certain wavelength with a specific identifier of the component including the wavelength. If the correspondence between the main signal and the auxiliary signal is maintained, it is determined that the information of the auxiliary signal is related to the corresponding main signal.

In operation, WDM 102 uses ASG
Auxiliary signal 122a is received from 132a, main signals 120a-c are received from client mappers 130a-c, and signals 122a and 120a-c are wavelength division multiplexed to form a composite signal 124a. Line amplifier 104
a receives the composite signal 124a from the WDM 102 and amplifies the signal 124a. The line amplifier 104a separates the auxiliary signal from the composite signal, optically amplifies the composite signal (excluding the auxiliary signal), and multiplexes a new auxiliary signal into the composite main signal. When the input synthesized signal is destroyed or interrupted, the line amplifier 104a inserts failure notification information for those main signals. The main signal portion of the composite signal cannot be accessed or modified in, for example, a branching process, an insertion process, or a wavelength conversion process for one main signal. Therefore, the line amplifier 104a cannot determine whether or not the correspondence between the signals is maintained.

The line amplifier 104b is a line amplifier 1
04a, receives the combined signal 124a, amplifies the signal 124a, and performs other processing on the combined signal similar to that performed by the line amplifier 104a. WADM106
Receives the combined signal 124a from the line amplifier 104b and wavelength separates the input signal 124a into an input auxiliary signal 122b and an input main signal to be split.

The WADM 106 converts the auxiliary signal 122b into an auxiliary signal terminator (AS).
T) 134a, and performs termination processing of the signal 122b.
The WADM 106 also generates an output main signal by inserting or branching the main signal into the input main signal. ASG 132b generates an auxiliary signal 122c that includes a specific identifier for the output main signal and other information,
The signal 122c is transmitted to the WADM 106. WADM
106 performs wavelength division multiplexing of the output auxiliary signal 122c and the output main signal to form a composite signal 124b. The line amplifier 104c receives the composite signal 124b from the WADM 106 and amplifies the composite signal 124b.

It is assumed that the failure 150 of the composite signal 124b occurs after the composite signal 124b is sent from the line amplifier 104 and before the signal 124b reaches the WADM 108. That is, it is assumed that the entire signal 124b including all the main signals and the auxiliary signal is destroyed by the failure 150. The WADM 108 receives the composite signal 124b from the line amplifier 104c and detects, for example, that the optical power level of the composite signal 124b and the separated auxiliary signal has decreased below a predetermined minimum threshold, thereby producing a composite signal 124b. The fault 150 of 124b is detected. WADM10
Reference numeral 8 demultiplexes or demultiplexes some main signals from the signal 124b, and wavelength-division multiplexes or combines a new main signal with the undemultiplexed main signal. ASG132c
Except for the multiplexed signal that is not affected by the impairment 150,
The failure notification information is inserted into all the main signals that have passed as the signal 124b. The WADM 108 outputs the auxiliary signal 12
2d and the output main signal are subjected to wavelength division multiplexing,
4c is formed.

The regenerative repeater 110 receives the combined signal 124c from the WADM 108, wavelength-division-divides the signal 124c, obtains an auxiliary signal 122d and an input main signal, and converts these signals into electric signals. In one embodiment of the present invention, the regenerative repeater 110 checks whether the correspondence between the auxiliary signal and the main signal has been lost by comparing the specific identifier of the input auxiliary signal 122d with the specific identifier of the input main signal. I do. If the specific identifier included in the component unique to the channel corresponding to the main signal does not match the specific identifier of the main signal, it is determined that the correspondence with the main signal has been lost. Here, it is assumed that the two specific identifiers match each other when they are the same or when they become the same after one or both are changed by a change process according to a predetermined instruction. When the specific identifiers match, the information included in the component of the auxiliary signal corresponds to the corresponding main signal, and can be used for determining the state of the input main signal. In the present embodiment, the regenerative repeater 110 determines whether or not the correspondence has been lost, and determines the state of the input main signal using the auxiliary signal 122d. The regenerative repeater 110 determines from the auxiliary signal 122d whether the WADM 108 has detected a failure that causes one or more failed main signals.

The AST 134c receives the auxiliary signal 122d from the regenerative repeater 110 and performs termination processing of the signal 122d. The reproduction repeater 110 performs a reproduction process such as a waveform shaping process on the signal, and reconverts the main signal into an optical signal.
The auxiliary signal generator 132d generates an auxiliary signal 122e having information on the output main signal. Regenerative repeater 110
Performs wavelength division multiplexing of the output main signal and the auxiliary signal 122e,
The combined signal 124d is formed.

The line amplifier 104d is connected to the regenerative repeater 11
From 0, the composite signal 124d is received, and the signal 124d is amplified. The OXC 112 receives the composite signal 124d from the line amplifier 104d and converts the signal 124d to the auxiliary signal 12d.
2e and the input main signal are subjected to wavelength division separation. AST134
d receives the auxiliary signal 122e from the OXC 112 and performs termination processing on the signal 122e. The OXC 112 allows the input main signal to pass to the output terminals 113a and 113b. OX
For example, the C112 may be configured to include more output terminals and input terminals. The ASG 132f is connected to the output terminal 113.
An auxiliary signal 122f comprising information about the output main signal passing through a is generated. The OXC 112 has an output terminal 113a.
Is subjected to wavelength division multiplexing of the main signal and the auxiliary signal 122f to form a composite signal 124e. Similarly, ASG13
2e generates an auxiliary signal 122g comprising information on the output main signal passing through the output end 113b. OXC11
2 is a main signal and an auxiliary signal 12 passing through the output end 113b.
2g is wavelength division multiplexed to form a composite signal 124f.

The line amplifier 104e receives the composite signal 124e from the OXC 112 and amplifies the signal 124e. The WDD 116 receives the composite signal 124e from the line amplifier 104e, performs wavelength division separation on the signal 124e, and obtains an auxiliary signal 122f and main signals 125a-c. A
ST 134e receives auxiliary signal 122f from WDD 116, and performs client demapper (client demapper).
(CD) 138a-c receive main signals 125a-c from WDD 116, respectively. Similarly, line amplifier 1
04f receives the composite signal 124f from the OXC 112,
The signal 124f is amplified. WDD 118 receives combined signal 124f from line amplifier 104f and
24f is subjected to wavelength division separation, and the auxiliary signal 122g and the main signal 1
29a-c. The AST 134f receives the auxiliary signal 122g from the WDD 118, and the client demappers 140a-c respectively receive the main signal 1 from the WDD 118.
29a-c are received.

In this embodiment, the main signal that has passed through the WADM 108 is a WD for checking the correspondence between the main signals.
Terminate at the client demapper connected to D116 or D118. The forward failure notification information related to the main signal affected by the failure 150 alerts the downstream network component that the failure that caused the main signal destruction has been detected upstream. This failure notification information is stored in the ASG 132
AST of each network component device sent from
The data is sequentially transferred to the downstream side by the / ASG function.

FIG. 2 is a diagram showing the configuration of an auxiliary signal 122a that can be used in the optical communication network of FIG. 1 to notify a main signal failure and other information according to the present invention. In the present embodiment, information is transmitted in a multi-frame format. The auxiliary signal 122a has channel-specific components, and each component has information on one main signal, for example, information 2 on the wavelength of the main signal 120a.
04a-c, specific identifiers 206a-c, and failure notification information 208a-c. Each channel-specific component corresponds to a main signal received at a particular wavelength, for example, a component having wavelengths 204a-c corresponds to a main signal received at wavelengths 204a-c. This component can take any suitable form, such as multiple fixed allocation bytes appearing in each frame of the auxiliary signal,
It can take the form using one or more fixed allocation bytes used in a multi-frame format. Another suitable format is one that utilizes one or more bytes used in the message-based channel. Here, no particular meaning is assigned to each bit of one or more bytes, but rather these bytes are used as data channels for transmitting various messages containing main signal information. Is done.

The channel-specific component has both a single frame allocation area and multi-frame allocation areas 202a-c, each of which includes a slot area for storing data relating to a particular main signal. For example, L204
Is a single frame fixed allocation area, and includes information on the wavelength of the main signal 120a. ID ₁ 206a, ID ₂
206b... ID _N 206c constitute an allocation area of a multi-frame format including a specific identifier of the main signal 120a.
The FDI 208 is a fixed allocation area for a single frame, and the main signal 1
15 shows forward failure notification information regarding 20a.

The above-mentioned specific identifier is for determining whether or not the information on the main signal stored in the auxiliary signal corresponds to the corresponding main signal. This particular identifier can be in any suitable format, for example, ITU
-T Recommendation G. 707, section 9.2.2.2 (Rege
A trace format based on nerator Section Trace (J0) can be used. FDI 208 is the main signal 12
0a is provided. This forward failure notification information notifies an upstream failure to a downstream network device. The failure notification information in the active state indicates a failure signal, and the failure notification information in the inactive state indicates a normal signal.

The information of the auxiliary signal 122a relating to a specific main signal can be accessed by using the wavelength of the main signal. For example, the network device can access information about the main signal received at the wavelength λ by reading data stored in the channel-specific component including the wavelength λ. The wavelength notification information L is, for example, a reference number corresponding to a specific wavelength or an encoded numerical value indicating an actual wavelength.

FIG. 3 shows one embodiment of the present invention.
1 is a block diagram of a wavelength multiplexing device (WDM) 102 that can be used in an optical communication network of FIG. Each of the client mappers (CM) 103a-c receives signal 1
20a-c, and the signals 120a-c are
Send to 2. The signals 120a-c are the main signal 1 of the composite signal.
20a-c. Client mapper 103a-c
Each convert a corresponding input signal into an electrical signal and add an overhead portion to the signal. The overhead part of each signal, in addition to the specific identifier and the failure notification information, if necessary, other appropriate information on the main signal, for example, a frame pattern, information related to the mapping process, bit interleave parity for error detection, It includes bit error notification information, forward error correction code, and client type indication information.

The various allocation areas in the main signal overhead section may be fixed to a single frame, fixed to a multi-frame, or
Some are message based. The format of the specific identifier of the main signal overhead section is the same as the format used for the main signal specific component of the auxiliary signal. The specific identifier and the failure notification information are inserted into the optical channel overhead. The ASG 132a generates the auxiliary signal 122a and transmits the signal 122a to the WDM 102. The auxiliary signal 122a includes a specific identifier, a wavelength of each of the main signals 120a-c, and failure notification information regarding each of the failed main signals. The failure notification information corresponds to a specific identifier of a main signal having a failure. WDM102
Multiplexes the auxiliary signal 122a and the main signals 120a-c to form a composite signal.

FIG. 4 shows an embodiment of the present invention.
FIG. 2 is a block diagram of a wavelength adder / dropper (WADM) 106 that can be used in the optical communication network of FIG. The combined signal 124a is transmitted through the receiving unit 406 to the WADM 106.
Sent to The WADM 106 performs wavelength division separation of the input auxiliary signal 122b and the main signal to be demultiplexed from the signal 124a. The WADM 106 outputs the auxiliary signal 122b as AST1.
34a. AST 134a is the auxiliary signal 122b
Is terminated.

The WADM 106 multiplexes or demultiplexes the main signal with the input main signal. Client Mapper 4
Signals transmitted from 04a-b are added by WADM 106 to output composite signal 124b. WADM106
The main signal demultiplexed is transmitted to the client demappers 402a-b. Each of the client demappers 402a-b removes information of an overhead section from each input signal and outputs a restored signal. Further, the client demappers 402a-b compare the specific identifier from the channel-specific component with the specific identifier of the main signal corresponding to the component to determine whether the correspondence between the auxiliary signal and the main signal has been lost. To check. If these specific identifiers do not match, it is determined that the correspondence with the main signal has been lost. Further, when the two specific identifiers match, it is determined that the failure notification information of the channel-specific component is related to the corresponding main signal.

The client demapper 402a
-C detects the state of the demultiplexed input main signal, and compares the detected state with the state of the failure notification information in the corresponding auxiliary signal 122b. If the corresponding failure notification information is active and indicates a failure signal, and if the received signal has a failure, it is determined that an upstream failure exists. On the other hand, if the failure notification information indicates a normal signal in the inactive state, but a failure such as signal loss or frame loss is present in the signal, it is determined that the failure is in the corresponding main signal. Further, when the signal is in the normal state and the corresponding specific identifier matches, the signal is determined to be in the normal state.

The ASG 132b outputs the output composite signal 124b.
, An auxiliary signal 122c including the wavelength of each output main signal, the specific identifier, and the failure notification information. WA
When the DM 106 detects a signal loss of the input composite signal 124a, the ASG 132b outputs
The failure notification information corresponding to each of the output main signals affected by the loss is activated. WADM10
6 caused the client mapper 404
If one or more of the multiplexed main signals from ab have been destroyed, WADM 106 outputs
The failure notification information corresponding to the main signal affected by b is activated. Further, the WADM 106 converts the main signal into a different wavelength. The WADM 106 outputs the auxiliary signal 1
22c, wavelength-division multiplexing of the undemultiplexed main signal and the main signal added from the client mappers 404a-b to form an output composite signal 124b. Synthetic signal 1
24b is transmitted from the output terminal 408.

FIG. 5 shows an embodiment of the present invention.
2 is a block diagram of an optical cross connect (OXC) 112 that can be used in the optical communication network of FIG. O
The XC 112 receives the composite signal 124d, and
The auxiliary signal 122e and the input main signal are obtained by wavelength division separation of d. AST 134d is an auxiliary signal 122e
From the OXC 112, and terminates the signal 122e. The OXC 112 passes the input main signal to two or more output terminals 113a, 113b. ASG132
f generates an auxiliary signal 122f comprising information about the output main signal passing through the output 113a. OXC112
Is the output main signal and auxiliary signal 1 passing through the output end 113a.
22f is subjected to wavelength division multiplexing to form an output composite signal 124e. Similarly, the ASG 132e is connected to the output terminal 113b.
Signal 1 with information about the output main signal passing through
Generates 22 g. The OXC 112 wavelength-division multiplexes the output main signal and the auxiliary signal 122g passing through the output terminal 113b to form an output composite signal 124f.

FIG. 6 shows an embodiment of the present invention.
1 is a block diagram of a regenerative repeater (RGN) 110 that can be used in the optical communication network of FIG. The synthesized signal 124c is transmitted to the WDD 602. WDD 602 converts auxiliary signal 122d and main signal 6 from input composite signal 124c.
03a-c are separated by wavelength division. The auxiliary signal 122d is transmitted to the AST 134c, where it is terminated. Each of the main signals 603a-c is a signal regenerative repeater (SR) 6
04a-c, where they are converted to electrical signals.

In one embodiment, the regenerative repeater 110
Is the specific identifier from the main signal 603a-c and the auxiliary signal 1
By comparing with the specific identifier from 22d, it is checked whether the correspondence between the main signal and the auxiliary signal is lost. If the identifiers do not match, it is determined that the correspondence has been lost. In addition, the regenerative repeater 110 detects the state of the main signal 603a, and compares the state with the failure notification information included in the channel-specific component corresponding to the main signal 603a. When the corresponding failure notification information is active,
If there is a failure in the main signal 603a, it is determined that an upstream failure exists. If the failure notification information is in an inactive state and the signal 603 has a specific failure, it is determined that the specific failure is in the corresponding signal. When the main signal 603a is in the normal state and the corresponding two specific identifiers match, it is determined that the signal is in the normal state.

When the WDD 602 detects a signal loss of an input signal, the ASG 132g activates failure notification information corresponding to each of the affected main signals among the output signals. If the signal regenerator 604a-c detects a faulty signal, the signal regenerator 604a-c
-C sets the failure notification information of the auxiliary signal corresponding to the affected main signal in the output composite signal 124d to the active state. Alternatively, the failure notification information may be directly inserted into the overhead portion of the main signal, or may be inserted into both the main signal and the auxiliary signal.

The ASG 132d calculates the wavelength of each output main signal,
Auxiliary signal 122e including specific identifier and failure notification information
Generate Each of the signal reproduction repeaters 604a-c performs a reproduction process such as a re-waveform shaping process on each of the corresponding main signals 603a-c, and reconverts the main signals 603a-c into optical signals. Also, the signal regeneration repeaters 604a-c convert the main signals 603a-c to different wavelengths. The output auxiliary signal 122e and the reproduced main signal are multiplexed to form an output composite signal 124d.

FIG. 7 shows an embodiment of the present invention.
FIG. 2 is a block diagram of a wavelength separation device (WDD) 118 that can be used in the optical communication network of FIG. The composite signal 124f is transmitted to the WDD 118. WDD118
Separates the auxiliary signal 122g and the input main signals 129a-c from the input composite signal 124f by wavelength division. AST134
f receives the auxiliary signal 122g and performs termination processing. The main signals 129a-c are transmitted to the client demappers (CD) 140a-c described in FIG.

FIG. 8 shows an embodiment of the present invention.
5 is a flowchart showing a method for generating an auxiliary signal of FIG. The method may be configured by a computer program.

The method starts at step 802. In this step, a specific identifier corresponding to the inserted or multiplexed main signal is inserted into the main signal. This specific identifier is inserted into the optical channel overhead section of the main signal. In step 804, a specific identifier corresponding to the output main signal is inserted into the output auxiliary signal. The output main signal is a main signal multiplexed or multiplexed with the input synthesized signal, or a main signal passed from the input synthesized signal. In the case of a passing signal, the specific identifier corresponding to one certain main signal can be read from the corresponding component of the input auxiliary signal. The specific identifier corresponding to the given main signal is input to the channel-specific component of the auxiliary signal corresponding to the main signal.

In step 805, the attributes of the plurality of output main signals are inserted into the auxiliary signal. This attribute includes the wavelength of the main signal and also includes the forward failure notification information of the signal. For a combined main signal, a multiplexed main signal, or a passing main signal that has been destroyed by a combined signal failure or an internal failure detected by the current network configuration device, forward failure notification information in an active state is sent. In the case where the network component can detect the failure of the main signal, if the input main signal is a passing signal having a failure and the forward failure notification information of the input auxiliary signal is received in an inactive state, the order of the active state is changed. Send direction failure notification information.

As for the passing main signal, part or all of the information from the corresponding component of the input auxiliary signal is inserted into the output auxiliary signal as it is or after correction. The input forward failure notification information in the active state can be passed, for example, by reading the notification information from the input auxiliary signal and inserting it into a predetermined component of the output auxiliary signal. Information such as the specific identifier and the format of the client signal is passed without modification. However, in the case of a composite signal failure, the last received corresponding specific identifier stored in the memory is sent. In the network device, when the wavelength of the main signal is changed, the wavelength display information is changed. The attribute information is inserted into a channel-specific component corresponding to the main signal.

In step 806, the output main signal and the auxiliary signal are subjected to wavelength division multiplexing to form a composite signal. In step 807, the combined signal is input to the next downstream network device. This network configuration device includes, for example, WADM 106, regenerative repeater 110, OXC 11
2. WDD 116.

FIGS. 9 and 10 are flowcharts showing a method for processing the auxiliary signal of FIG. 2 for determining the correspondence with the main signal in one embodiment of the present invention. The method compares a specific identifier from the main signal with a specific identifier from the auxiliary signal. If these identifiers match, an auxiliary signal can be used to provide information about the main signal. If the two identifiers do not match, it is determined that the correspondence has been lost. The method may comprise a computer program encoded and stored on a computer readable medium.

The method is a hardware process in which the network constituting device detects a composite signal, step 808.
Started from. If no synthesized signal is detected,
At step 810, it is determined that the combined signal is faulty. Next, FIG.
As described in step 805, the failure notification information for the passing main signal is inserted. If a synthesized signal is detected, for example, if the optical power level of either the main signal portion or the auxiliary signal is greater than a predetermined minimum threshold value, the hardware processing of step 812 may include A component separates the auxiliary signal from the plurality of main signals. Further, the separation of the auxiliary signal and the main signal may be performed before step 808. In step 813, the network component determines whether the auxiliary signal is a good signal. A good signal is, for example, a signal that exceeds a predetermined minimum optical power threshold, is framingable, and / or has a certain repetitive pattern. If the auxiliary signal is not a good signal,
In step 816, the network component determines the auxiliary signal failure and in step 822 checks the separated or regenerated main signal.

Returning to step 813, if the auxiliary signal is good, in step 820, the network constituting apparatus determines, from the component of the auxiliary signal corresponding to the main signal, the specific identifier ID _A corresponding to the main signal and the failure notification. Read the information DI _a. The network configuration device performs this reading process by, for example, reading information included in a component including the reception wavelength of the main signal. The network components are
To save a specific identifier ID _A in step 821, checks the main signal separated or reproduced in step 822.

If there is no main signal separated or reproduced in step 822, the network component checks the output (multiplexed or passed) main signal in step 890. If no main signal has been multiplexed or passed, the method ends. If there is a multiplexed or passed main signal, the process returns to step 802 in FIG. 8, and as described above, the network component device outputs, to the output auxiliary signal, the corresponding wavelength, the specific identifier ID _A , and / or to insert information such as fault notification information DI _a.

Returning to step 822, if the main signal is separated or reproduced in the network device, the main signal is separated from the composite signal by the hardware processing in step 823. At step 824, the network component determines whether the main signal is a good signal. A good signal may be, for example, above a predetermined minimum optical power threshold, frameable, and / or
Alternatively, it is a signal having a specific repetition pattern. If the main signal is a good signal, step 83
In step 2, the specific identifier ID _C of the main signal is read, and step 8
At step 834, it is compared with the specific identifier ID _A of the auxiliary signal to determine whether they match. Further, it may be configured to compare the specified identification ID _A of the auxiliary signal in a particular identifier and a service providing processing period stored in the memory.

Returning to step 824, if the signal is not good, proceed to step 834, where the main signal 120
comparing the specific identifier ID _A of the specific identifier ID _C and the auxiliary signal a, to determine whether these identifiers are matched.
In step 834, if the two identifiers are the same, or if one or both of the two identifiers become the same after being corrected by a predetermined correction method, it is determined that the two identifiers match. If the two identifiers do not match, the network device determines that the correspondence between the main signal and the information of the corresponding auxiliary signal has been lost, and requests transmission in step 836. In step 840, it is checked whether the received main signal is good. If the main signal is good, it is determined in step 842 that there is a signal, and the flow advances to step 890 to check the output main signal. If the main signal is not good, it is determined in step 844 that the signal has failed, and the flow advances to step 890 to check the output main signal. In steps 824 and 844, it is determined that the correspondence has been lost. However, the processing after step 840 is performed to determine the status information as to whether the main signal has been received.

Returning to step 834, if the above values match, then in step 850 the network component checks whether the signal is good. If the signal is good, it is determined in step 852 that the signal is normal, and the flow advances to step 890 to check the output main signal. If the signal is not good, step 85
Failure notification information DI _A at 4 to check whether there is in the active state. If the fault notification information DI _A is not in the active state, the network configuration device determines that local failure at step 856, a check of the main output signal proceeds to step 890. Failure notification information DI _A
Is in the active state, it is determined in step 856 that the network component device has failed on the upstream side, and the flow advances to step 890 to check the output main signal.

If there is no multiplexed main signal and no passing main signal in step 890, the method ends. If there is a multiplexed main signal or a passing main signal, the process returns to step 802 in FIG. 8, and the network device responds to the output auxiliary signal as described above with reference to FIG. Wavelength, specific identifier I
D _A, and / or to insert information such as fault notification information DI _A. The above steps are activated or executed by hardware, software or a combination of both.

[0057]

The technical effect of the present invention is that the method and system for transmitting auxiliary information relating to the main signal in the optical network transmission system are improved. In particular, a specific identifier corresponding to the main signal is transmitted as a component of the auxiliary signal. By using this identifier, it is checked whether the information of the auxiliary signal matches the corresponding main signal. Therefore, according to the present invention, it is possible to effectively identify a signal failure in an optical network.

[Brief description of the drawings]

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

FIG. 2 is an explanatory diagram showing auxiliary signals that can be used for notifying information about a main signal and a failure in the optical communication network of FIG. 1;

FIG. 3 is a block diagram of a wavelength division multiplexing device that can be used in the optical communication network of FIG. 1;

FIG. 4 is a block diagram of a wavelength adder / dropper that can be used in the optical communication network of FIG. 1;

FIG. 5 is a block diagram of an optical cross-connect that can be used in the optical communication network of FIG.

FIG. 6 is a block diagram of a signal regeneration repeater that can be used in the optical communication network of FIG. 1;

FIG. 7 is a block diagram of a wavelength separation device that can be used in the optical communication network of FIG. 1;

FIG. 8 is a flowchart illustrating a method of generating the auxiliary signal of FIG. 2;

FIG. 9 is a flowchart illustrating a method of processing the auxiliary signal of FIG. 2 in the optical network device to determine the correspondence with the main signal.

FIG. 10 is a flowchart showing a method of processing the auxiliary signal of FIG. 2 in the optical network device to determine the correspondence with the main signal.

[Explanation of symbols]

100: Optical communication network system, 102: Wavelength multiplexing device, 104a-f: Line amplifier, 106, 108
.., Wavelength adder, 110, regenerative repeater, 112, optical cross connect, 116, 118, wavelength demultiplexer.

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (reference) H04J 3/14

Claims (35)

[Claims] 1. A network configuration device included in a wavelength division multiplexing transmission system, comprising: a plurality of main signals each having an identifier and having a wavelength different from each other; and an identifier corresponding to each of the plurality of main signals (hereinafter referred to as a corresponding identifier). ) Receiving means for receiving a combined signal having an auxiliary signal having a component having each of the components, and connecting the receiving means, and comparing an identifier from the main signal with a corresponding identifier from the component corresponding to the main signal. A network configuration apparatus comprising: a correspondence determination unit that determines that the correspondence has been lost when the identifier from the main signal does not match the correspondence identifier from the component. 2. An apparatus according to claim 1, wherein said main signal includes an optical channel overhead unit having said identifier. 3. The network configuration device according to claim 1, wherein said identifier is received in a plurality of frames. 4. The network configuration device according to claim 1, wherein said correspondence identifier is received in a plurality of frames. 5. The network configuration device according to claim 1, wherein the component corresponding to the main signal has an attribute related to the main signal. 6. The network configuration device according to claim 5, wherein the attribute is failure notification information. 7. The network configuration device according to claim 1, wherein the network configuration device detects a state of the main signal and transmits an attribute corresponding to the state of the main signal by the auxiliary signal. 8. The network configuration device according to claim 1, further comprising a separating unit that separates the synthesized signal into the main signal and the auxiliary signal. 9. The network configuration device according to claim 1, wherein the identifier is a specific identifier different from others. 10. A method for judging correspondence between signals in a wavelength division multiplexing transmission network, comprising: a plurality of main signals each having an identifier and having a different wavelength; and an identifier corresponding to each of the plurality of main signals. Receiving an synthesized signal comprising an auxiliary signal having a component having each of the following, comparing an identifier from the main signal with a corresponding identifier from the component relating to the main signal, and comparing the identifier from the main signal and the component from the component. If the correspondence identifier does not match, it is determined that the correspondence has been lost. 11. The method according to claim 10, wherein said main signal comprises an optical channel overhead unit having said identifier. 12. The method of claim 10, wherein said identifier is received in a plurality of frames. 13. The method according to claim 10, wherein said correspondence identifier is received in a plurality of frames. 14. The method according to claim 10, wherein the component related to the main signal has an attribute corresponding to the main signal. 15. The method according to claim 14, wherein said attribute is failure notification information. 16. The method according to claim 10, further comprising a step of detecting a state of the main signal and transmitting an attribute corresponding to the state of the main signal in the auxiliary signal. 17. The method according to claim 10, further comprising a step of separating said composite signal into said main signal and said auxiliary signal. 18. The method according to claim 10, further comprising a step of requesting a retransmission of the synthesized signal when it is determined that the correspondence has been lost. 19. The method of claim 10, wherein the identifier is a specific identifier different from the others. 20. A system for detecting a loss of correspondence, comprising: a computer-readable medium; and a computer program encoded on the computer-readable medium. Comparing an identifier received from one of the plurality of main signals included in the composite signal with a corresponding identifier received from a component of the auxiliary signal included in the composite signal corresponding to the one main signal; If the identifier from the main signal and the corresponding identifier from the component do not match, it is determined that the correspondence has been lost, and the synthesized signal includes a plurality of main signals having different wavelengths from each other. A system characterized by the following. 21. The system according to claim 20, wherein said main signal comprises an optical channel overhead unit having said identifier. 22. The system of claim 20, wherein said identifier is received in a plurality of frames. 23. The system according to claim 20, wherein said correspondence identifier is received in a plurality of frames. 24. The system according to claim 20, wherein the component corresponding to the main signal has an attribute related to the main signal. 25. The system according to claim 24, wherein said attribute is failure notification information. 26. The system according to claim 20, wherein said computer program further activates detection of a state of a main signal and transmission of an attribute corresponding to the state of said main signal with said auxiliary signal. 27. The computer program according to claim 20, further comprising, when it is determined that the correspondence has been lost, requests retransmission of said composite signal.
The described system. 28. The system according to claim 20, wherein the identifier is a specific identifier different from the others. 29. A wavelength division multiplexing transmission system, comprising: a plurality of network components connected to each other by an optical transmission medium; and a plurality of main signals each having an identifier connected to one of the plurality of network components. An auxiliary signal generation unit that generates an auxiliary signal including a corresponding component, and includes a corresponding identifier in each component; and the optical transmission medium, wherein the plurality of main signals and the auxiliary signal are combined at different wavelengths into one combined signal. Receiving a composite signal comprising a first network component to be transmitted above, and a plurality of main signals and an auxiliary signal including a plurality of components corresponding to the plurality of main signals; and an identifier included in the main signal. And a second network component for determining whether the corresponding component and the main signal have a corresponding relationship based on the corresponding identifier included in the component. Wavelength multiplexing transmission system. 30. The system according to claim 29, wherein said main signal comprises an optical channel overhead unit having said identifier. 31. The system according to claim 29, wherein said identifier is received in a plurality of frames. 32. The system according to claim 29, wherein the component corresponding to the main signal has an attribute related to the main signal. 33. The system according to claim 32, wherein said attribute is failure notification information. 34. The system according to claim 29, wherein said first network component detects a state of a main signal and transmits an attribute corresponding to the state of said main signal in said auxiliary signal. 35. The system according to claim 29, wherein said identifier is a specific identifier different from others.