JP3478247B2 - Wrong connection monitoring system and wrong connection monitoring method for optical wavelength multiplexing apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an erroneous connection monitoring system and an erroneous connection monitoring method for an optical wavelength division multiplexer, for example, an erroneous optical wavelength division multiplexer for detecting an erroneous connection between an optical wavelength demultiplexer and a wavelength converter. The present invention relates to a connection monitoring system and an erroneous connection monitoring method.

[0002]

2. Description of the Related Art Conventionally, an erroneous connection monitoring system and an erroneous connection monitoring method for an optical wavelength division multiplexer are, for example, a DWDM (dynamic wavelength division multiplex) which is a backbone device.
) An erroneous connection monitoring system for an optical wavelength division multiplexer that detects the presence or absence of an erroneous connection between the optical wavelength demultiplexer and the wavelength converter in the state of connection between the wavelength converter and the optical wavelength multiplexer of the device and the circuit configuration state, and It is applied to the misconnection monitoring method.

Prior invention example 1 similar in technical field to the present invention
There is Japanese Patent Laid-Open No. 2000-41024. The invention example 1 of the prior application provides a wavelength division multiplex transmission apparatus, method, system, etc. capable of collating signals of a plurality of wavelengths transmitted by the wavelength division multiplex transmission method, respectively, and easily performing wavelength management. Disclosure.

Further, Japanese Unexamined Patent Publication No. 2000 as a prior invention example 2
Japanese Patent Publication No. 41026 discloses a detection method for appropriately detecting a signal disconnection state of each wavelength in an NB-WDM system.

In the prior art, as shown in the above-mentioned prior invention example 1, in a main signal system network consisting of a transmitting side terminal device, an optical multiplexer, an optical demultiplexer and a receiving side terminal device, The optical wavelength value data inserted into the main signal at the transmitting end terminal device is separated from the main signal at the receiving end terminal device and compared with the expected optical wavelength value data, resulting in erroneous connection. That can be detected.

The connection between a plurality of transmission side terminal equipments and an optical multiplexer, the connection between an optical demultiplexer and a plurality of reception side terminal equipments, etc. are as shown in the above-mentioned prior invention example 2. In the input of the optical multiplexer and the output of the optical demultiplexer, a photoelectric detection element (PD) is mounted for each wavelength, and the input / output level of light can be monitored. This makes it possible to judge whether or not the connection is normal, though it is impossible to judge the incorrect connection.

Based on the above, an example of the prior art is shown in FIGS. 3 and 4, and the contents of the prior art will be described in more detail. 3 and 4 respectively configure the same misconnection monitoring device. FIG. 3 shows the configuration of the transmission side device in detail, and FIG. 4 shows the configuration of the reception side device in detail. First, the transmission side apparatus will be described with reference to FIG. This transmission side device is roughly configured to include the following two types as the transmission side terminal station device that outputs the main signal input to the transmission side wavelength multiplexing device JNE3.

11); Transmission-side terminal station device JNE1 This device outputs an optical wavelength capable of direct optical multiplexing in the optical-wavelength multiplexing unit JC9 of the transmission-side wavelength multiplexing device JNE3. In FIG. 3, the main signal JS3 is output at the optical wavelength λ1.

12); Transmitting side terminal device JNE2 In this device, the optical wavelength multiplexing unit JC9 of the transmitting side wavelength multiplexing device JNE3 outputs an optical wavelength that cannot be directly multiplexed. In FIG. 3, the main signal JS5 is output at the optical wavelength λX.

The two types will be described individually. In the transmitting side terminal device JNE1 of 11), the connection management information JS12 managed by the control / alarm monitoring unit is passed to the connection management information insertion unit JC1, and the main signal (electricity) JS1 (not used This connection management information is inserted (in the overhead bits etc.) and the main signal JS2 is output. Electricity-
The E / O of the optical conversion unit outputs the main signal JS2 of the electric signal as the main signal JS3 having the optical wavelength λ1 of the optical signal.

In the transmission side wavelength division multiplexer JNE3, the main signal is branched at the optical branching portion for the purpose of fault isolation before the optical wavelength division multiplexing, and the electric signal (optical level monitoring signal JS13) is divided by the photoelectric detection element. Is converted into the optical level monitoring section JC14, and the optical level monitoring section detects the optical power level from the optical level monitoring signal JS13 and outputs the optical level information JS14 to the control / alarm monitoring section JC14.
give. The control / warning monitoring unit JC14 monitors the fluctuation of the received light level information JS14 or the magnitude relationship with a certain threshold. With this, it is determined whether or not the input main signal has a failure.

12); The other transmission side terminal device JNE2 outputs the (electrical) main signal JS4 and the electro-optical converting section JC4 outputs the (optical) main signal JS5 having the optical wavelength λX. In the transmission side wavelength multiplexing device JNE3, since the optical wavelength λX cannot directly implement the optical wavelength multiplexing, it is input to the wavelength conversion unit JC5 for converting into the optical wavelength λ2 capable of the optical wavelength multiplexing. In the wavelength converter JC5, the optical-electrical converter (O /
E) The main signal JS6 which is an electric signal is generated through the JC6, and the optical wavelength λ2 is generated by the electric-optical conversion unit (E / O) JC7.
An optical signal JS7 is generated.

The main signal is the transmission side terminal equipment JNE of 11).
1. Optical branching section JC3 and photoelectric detection element (PD) J described in 1.
C12 and light level monitoring unit JC13 are commonly used,
The light level is monitored for fault isolation (block 3). Further, the main signals JS3 (λ1), JS5 (λ2), JS8 input as in 11) and 12).
N wavelengths of (λ3) and JS9 (λN) are multiplexed by the optical wavelength multiplexing unit JC9 to form the main signal JS10, which is output from the device as the main signal JS11 in which the optical power is amplified by the optical amplification unit JC10. Will be done.

Next, the receiving side wavelength division multiplexer JNE4 will be described with reference to FIG. The main signal JS15 transmitted from the transmitting side passes through the optical amplification section JC15 and the optical wavelength demultiplexing section JC16, and the main signals are JS17 (λ1) and JS2.
0 (λ2), JS24 (λ3), JS25 (λN) N
Separated into books. Transmission-side terminal device J shown in the transmission-side device
The receiving side terminal station devices JN5 and JN6 are present as devices for receiving the main signals output from N1 and JN2. The correlation between them is as follows. 21) The transmission-side terminal device JNE1 and the receiving-side terminal device JNE5 are compared. 22) The transmission side terminal device JNE2 and the reception side terminal device JNE6 are compared.

In the above 21), the signal JS17 output from the optical wavelength demultiplexing unit JC16 is directly received by the terminal device JNE on the receiving side.
5 is being sent. However, as described with reference to FIG. 3, the optical branching unit JC shown in the block 6 is used for the purpose of isolating the failure.
17, photoelectric detector JC25, optical level monitor JC26
The optical power level is detected by using the and the failure analysis is performed.

In the receiving side terminal device JNE5, an electric signal JS18 is generated in the optical-electrical conversion section (O / E) JC18, and the connection management information inserted in the transmitting side terminal device JNE1 is separated and controlled. -It is sent to the alarm monitoring unit JC28 as connection management information JS27.

The control / alarm monitoring unit JC28 receives the connection management information JS27 sent, judges whether the connection destination is correct, and from this result it is possible to detect an incorrect connection.

22), the signal JS20 output from the optical wavelength demultiplexing unit JC16 passes through the JC20 of the block 6,
The optical level is monitored, and the wavelength conversion unit JC21 converts the optical wavelength λX that can be received by the receiving side terminal device JNE6 and outputs the optical wavelength λX. In the receiving side terminal device JNE6, the optical-
The main signal JS23 as an electric signal in the electric conversion unit JC24
Is generated and taken into the control / alarm section from the ID number separation section in the device.

The signals λ3 to λN output from the other optical wavelength demultiplexing unit JC16 are processed in the same manner as the above 11) and 12) and output to the outside of the device.

[0020]

However, the above-mentioned prior art involves the following problems. The first problem is a) between a plurality of transmission side terminal stations and an optical wavelength multiplexer, b) between an optical wavelength demultiplexer and a plurality of receiving side terminal stations, and c) an optical wavelength multiplexer and an optical wavelength demultiplexer. It is impossible to distinguish the connection error with

The reason is that the optical wavelength multiplexer and the optical wavelength demultiplexer do not have a circuit for understanding the information in the main signal. This is also because the optical wavelength division multiplexer is a device that does not consider the content of the main signal, the transmission speed, and the like.

The second problem is that the type of signal predicted to be transmitted when the optical wavelength multiplexer and the optical wavelength demultiplexer are designed to monitor the information in the main signal for each wave (what kind of Depending on the information such as the frame structure and what kind of transmission speed), a circuit and a switching circuit to be individually monitored are required, which increases the circuit scale.

The present invention makes it possible to confirm erroneous connection at the time of starting up the device, limit erroneous connection locations as much as possible, suppress increase in circuit scale as much as possible, and improve reliability of the optical wavelength division multiplexer. An object is to provide a connection monitoring system and an erroneous connection monitoring method.

[0024]

In order to achieve the above object, a transmitting side terminal equipment (NE1) according to the invention as defined in claim 1 is provided.
In an erroneous connection monitoring system for an optical wavelength division multiplexer, which is a backbone device configured to be connected to a transmission side wavelength division multiplexer (NE3), the transmission side terminal station equipment (NE1) transmits connection management information different from the main signal. A connection management information generation unit of a function unit to be generated, and a first control / warning monitoring unit (C12) that manages the connection management information generated by the connection management information generation unit in a device alarm, a device configuration, setting information, and the like. And the first control
The connection management information is sent in place of the main signal in response to an erroneous connection monitoring request which is an instruction from the alarm monitoring unit (C12).
The signal switching unit (C which outputs to the receiving side wavelength division multiplexer (NE3)
1) and the transmission side wavelength division multiplexer (N
In front of the input unit of E3) , an optical branching unit (C3) for separating the optical input signal, and an optical level monitoring signal and connection management information are separated from the optical input signal separated by the optical branching unit (C3). A photoelectric detection element (C13) and an optical level monitoring section (C1) for detecting an optical power level from the optical level monitoring signal.
5) and a connection management information interpretation unit (C14) that interprets the connection management information from the photoelectric detection element (C13), and includes a functional unit, a wavelength signal unit , and various connection management information. The feature is that it is possible to monitor the presence or absence of incorrect connection and function maintenance for each.

The above-mentioned monitoring is performed at the time of a wrong connection monitoring request from the control / warning monitoring unit (C12), and the presence or absence of a wrong connection is monitored by the connection management information from the connection management information interpreting unit (C14). It is preferable that the monitoring of the function maintenance is performed based on the optical power level detected by the optical level monitoring unit (C15).

In addition, a second for performing function maintenance monitoring
The optical wavelength division multiplexer includes a transmission side wavelength division multiplexer and a reception side wavelength division multiplexer, and monitors the presence / absence of erroneous connection and function maintenance for each component.
It is preferable to be executable on both the transmitting side and the receiving side.

The transmitting-side terminal station device according to the invention of claim 7
(NE1) and a transmission side wavelength division multiplexer ( NE3) are connected to each other. In the optical wavelength division multiplexer misconnection monitoring method of the optical wavelength division multiplexer which is a backbone system apparatus, the transmission side terminal station equipment is provided.
(NE1) is a connection management information generation process of a functional unit that generates connection management information different from the main signal, and the connection management information generated in this connection management information generation process in device alarms, device configuration, setting information, etc. a control and alarm monitoring step of managing, transmitting-side wave connection management information instead of the main signal by instructing a is erroneous connection monitoring request from the control and alarm monitoring step
And a signal switching step of outputting to the long multiplexer (NE3) . In addition, an optical branching step for separating the optical input signal and an optical level monitoring signal and connection management information from the optical input signal separated by this optical branching step are provided in the preceding stage of the input section of the transmission side wavelength division multiplexer (NE3). a photoelectric detection step of separating further comprises an optical level monitoring step of detecting a light power level from the light level monitor signal, and a connection management information interpretation step of interpreting the connection management information from the photoelectric detection step, function unit, wavelength signal portion, characterized in that to enable the various connection management information, whether the functional unit each misconnection including and functions of the maintenance monitoring.

The above-mentioned monitoring is performed at the time of a request for erroneous connection monitoring from the control / alarm monitoring process, and the presence / absence of erroneous connection is monitored based on the connection management information from the connection management information interpretation process. The maintenance is monitored based on the optical power level detected in the optical level monitoring step, and it is preferable that both the transmitting side and the receiving side can monitor the presence or absence of an erroneous connection for each functional unit and the function maintenance.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION Next, embodiments of an erroneous connection monitoring system and an erroneous connection monitoring method for an optical wavelength division multiplexer according to the present invention will be described in detail with reference to the accompanying drawings. 1 and 2, there is shown an embodiment of an erroneous connection monitoring system and an erroneous connection monitoring method for an optical wavelength division multiplexer according to the present invention.

Next, embodiments of the present invention will be described in detail with reference to the drawings. 1 and 2 show an example of the configuration of this embodiment. FIG. 1 shows the terminal device and the transmission side device of the optical wavelength division multiplexer in more detail, and FIG. 2 shows the reception side device in more detail. Further, in this figure, as an embodiment, a case where the present invention is implemented in a configuration in which an optical wavelength for optical wavelength multiplexing is directly input / output from the terminal station device, Two points, that is, the case where the present invention is implemented in the configuration where the wavelength is input and output, are described.

In FIG. 1, the transmission side apparatus of the misconnection monitoring system and the misconnection monitoring method for an optical wavelength division multiplexer is a transmission side terminal station apparatus 1 (NE1) and a transmission side terminal station apparatus 2 (NE).
2) and a transmission side wavelength division multiplexer (NE3).

The transmission side terminal equipment 1 (NE1) and the transmission side terminal equipment 2 (NE2) respectively include a signal switching unit C1 and
It is configured to include an electric-optical conversion unit C2, a connection management information generation unit C11, and a control / warning monitoring unit C12.

The wavelength multiplexer (NE3) on the transmission side includes a wavelength converter C5 having an opto-electric converter C6 and a block 1 (C7), an optical splitter C3, a photoelectric detector (PD) C13, and connection management information. A block 2 (C8) including an interpreter C14 and an optical level monitor C15, an optical wavelength multiplexer C9, an optical amplifier C10, and a control / alarm monitor C16 are provided.

In FIG. 2, the reception side apparatus of the misconnection monitoring system and the misconnection monitoring method for the optical wavelength division multiplexer is the reception side wavelength division multiplexer (NE4) and the reception side terminal equipment (NE).
5) and a receiving side terminal device (NE6).

The receiving side wavelength division multiplexer (NE4) includes an optical amplifier C17, an optical wavelength demultiplexer C18, an optical splitter C19, a photoelectric detector (PD) C26, a connection management information interpreter C27 and an optical level monitor C28. Block 3 (C2
1), a wavelength conversion unit C22 including an electro-optical conversion unit C24 and a block 4 (C23), a control / alarm monitoring unit C2
9, and is comprised.

The receiving-side terminal equipment (NE5) and the receiving-side terminal equipment (NE6) respectively have an optical-electrical conversion section C20.
And a block 4 having a connection management information interpretation unit C30, and a control / warning monitoring unit C31.

(Example of operation) First, as a precondition, as described in the prior art, the connection between the transmission / reception side terminal equipment and the transmission / reception wavelength division multiplexer is roughly divided into the following 1) and 2). Exists. 1) When the transmission / reception side terminal device is connected to the optical wavelength multiplexing unit in the transmission / reception wavelength multiplexing device at an optical wavelength that can be directly connected, and 2) Optical wavelength multiplexing in the transmission / reception side terminal device and the transmission / reception wavelength multiplexing device. Each of the operation examples when the wavelength conversion unit is required in the transmission / reception wavelength multiplexing apparatus because the optical wavelengths are not directly connected to the unit will be individually described.

The operation on the transmitting side will be described with reference to FIG. In the case of 1): In the transmission side terminal device NE1, the connection management information generating unit C11 extracts the management information S13 obtained from the control / warning monitoring unit C12 when the signal is a low-speed signal and this signal is received. As much as possible, a signal including a frame bit and a check bit for detecting an error in information is generated and output as connection management information S14. In the above, the connection management information generation unit C11
Is a functional unit that generates connection management information different from the main signal. The check bit means, for example, a parity bit or the like.

When the erroneous connection monitoring request S12 is issued in the control / alarm monitoring section C12, the signal switching section C
At 1, the main signal S1 is switched to the connection management information S14. As a result, the connection management information is output as the main signal S2, becomes the optical signal S3 of the optical wavelength λ1 in the electrical-optical conversion section C2, and is output from the transmitting end terminal device 1.

In the transmission side wavelength division multiplexer NE3, the optical branching section C3 branches the output to the optical wavelength division section C9 and the signal for monitoring the optical level.

From the photoelectric detection element C13 which receives the main signal S3 output from the optical branching section C3, the optical level monitoring signal S
15 is output as an electric signal. Here, the above-mentioned low-speed connection management information S14 is extracted as a signal by the photoelectric detection element C13, and the connection management information interpretation unit C1
By the frame bit and check bit in 4,
The connection management information can be normally extracted and transmitted to the control / alarm monitoring unit C16 as the connection management information S16.
The control / warning monitoring unit C16 determines whether the received connection management information is normal, and this determination is detection of an incorrect connection. Note that a high-speed signal such as the main signal cannot be extracted as a normal signal by the photoelectric detection element C13.

The monitoring of the light level may be similar to the procedure described in the prior art. In the case of 2), the main signal S having the optical wavelength λX output from the transmission side terminal device NE2
5, the wavelength conversion unit C in the transmission side wavelength division multiplexer NE3
5, the optical signal S7 having the optical wavelength λ2 is converted.
However, 1) the signal switching unit C in the transmission side terminal device NE1
1. Connection management information generation unit C11 and electro-optical conversion unit C2
This wavelength conversion unit C5 also has the same circuit block 1 as the above. Therefore, the connection management information is transmitted to the main signal S7 in response to the incorrect connection monitoring request S18 from the control / warning monitoring unit C16. The erroneous connection monitoring request S18 refers to an instruction from the control / warning monitoring unit C16 that manages a device alarm, a device configuration, and setting information.

In 1), the same circuit as the block 2 including the optical branching unit C3 is provided in C8, and the connection management information S19 inserted in the wavelength converting unit C5 can be extracted. Is also detectable.

The N signals (S3, S7 to S8) that have undergone the above processing are input to the optical wavelength multiplexer C9,
The optical-multiplexed main signal S10 passes through the optical amplifier C10 and is output as the main signal S11 to the outside of the transmission side wavelength multiplexing apparatus NE3.

Next, the receiving side will be described with reference to FIG. The main signal S20 transmitted from the transmitting side passes through the optical amplification section C17 and the optical wavelength demultiplexing section C18, and the N signals S22 (λ1) and S2 are transmitted.
4 (λ2) and S28 (λ3) to S29 (λN).

In the case of 1), the optical branching unit C19 branches the main signal S22 for optical level monitoring, and the photoelectric detecting element C
At 26, an optical level monitoring signal S30 is generated. However,
When the transmission side transmits low-speed connection management information, the photoelectric detection element C26 extracts the connection management information, and the connection management information interpretation unit C27 interprets the connection management information. On the basis of this information, the control / warning monitoring unit C29 can determine the incorrect connection.

In the receiving side terminal device NE5, the optical-electrical conversion unit C20 generates an electric signal S23, and the connection management information interpretation unit C30 interprets the connection management information. On the basis of this information, the control / alarm monitoring unit C31 will determine the incorrect connection.

In the case of 2), the main signal S24 demultiplexed by the optical wavelength demultiplexing unit C18 has connection management information interpreted and controlled by the circuit block 3 (C21) similar to that of 1).
An erroneous connection is determined in the alarm monitoring unit C29.

Further, the wavelength conversion unit C22 has the same circuit configuration as the block 4 (C2) of the optical-electrical conversion unit C20 and the connection management information interpretation unit C30 shown in the receiving side terminal device NE5.
3), the connection management information S33 is extracted from the main signal S24. Further, from the extracted connection management information S33, the control / warning monitoring unit C29 can determine an erroneous connection.

The main signal S25 passes through the electro-optical conversion section C24 to become an optical signal S26 having an optical wavelength λX, and is transmitted to the receiving side terminal station device NE6. The operations 1) and 2) are also performed on the remaining signals of λ3 to λN. The above is the flow of signals, and each connection management information interpretation unit C30 can individually determine erroneous connection. This makes it possible to limit the locations of erroneous connections.

In the above embodiment, in order to detect an erroneous connection, the main signal is once cut off and the connection management information is transferred instead of the main signal. As a result, the connection management information transmitted in place of the main signal is extracted at each portion where erroneous connection detection is required. It is possible to determine an erroneous connection from the extracted connection management information.

In the wavelength converting section C5 of the transmitting side terminal equipments NE1 and NE2 and the transmitting side wavelength multiplexing apparatus NE3, a connection management information generating section for generating the connection management information as a low speed signal, and this connection management information generating section It has a signal switching unit C1 for switching the connection management information and the main signal thus generated based on an erroneous connection monitoring request from the control / warning monitoring unit C16. In addition,
The connection management information generation unit is a functional unit that generates connection management information different from the main signal. A false connection monitoring request is a control / control that manages device alarms, device configuration, and setting information.
It is an instruction from the alarm monitoring units C12 and C16.

Further, the optical level monitoring section C15 on the input side of the optical wavelength multiplexing section C9 of the transmitting side wavelength multiplexing apparatus NE3 and the optical level monitoring section C28 and the wavelength converting section C22 on the optical output section of the receiving side wavelength multiplexing apparatus NE4. In the portion (2), the connection management information interpretation units C14 and C27 that receive signals generated from the photoelectric detection elements C13 and C26 and the photoelectric conversion unit C6 and extract low-speed signals are provided. The low-speed signal mentioned above refers to connection management information.

However, the connection management information (low-speed signal) described here is prepared for optical level monitoring,
The photoelectric detection elements C13 and C26 are set to a speed at which they can be sufficiently extracted as signals. In this embodiment, several hundreds bits / second is assumed.

(Effect) The first effect is that it is possible to determine the incorrect connection at the connection point of each optical signal, which is useful for limiting the failure location. The second effect is that the circuit scale can be suppressed. The reason is that the photoelectric detection element, which is the circuit used in the prior art, is also used. In addition, in order to be able to use the photoelectric detection element, the connection management information is normally extracted as a signal.

If high-speed information is input, a circuit that can normally extract a higher-speed signal, a circuit that separates information from a part of bits in the main signal at a higher speed, etc. are required. . As a result, it is obvious that the circuit becomes bloated. Note that the high-speed information in this case is the information included in the main signal as in the prior art. If such high-speed information is input, for example, the photoelectric conversion unit in the figure requires a circuit capable of higher-speed processing.

The above-mentioned embodiment is an example of a preferred embodiment of the present invention. However, it is not limited to this,
Various modifications can be made without departing from the scope of the present invention.

[0058]

As is apparent from the above description, in the erroneous connection monitoring system and the erroneous connection monitoring method for an optical wavelength division multiplexer according to the present invention, in order to detect an erroneous connection, the main signal is temporarily disconnected to manage the connection. Transfer information instead of the main signal. The connection management information transmitted in place of the main signal is extracted at each portion where erroneous connection detection is required. It is possible to determine an erroneous connection from the extracted connection management information. Furthermore, by making the connection management information a low speed signal as compared with the main signal, it becomes easier to construct a circuit.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an erroneous connection monitoring system and an erroneous connection monitoring method for an optical wavelength division multiplexer according to the present invention, showing the transmitting side in detail.

FIG. 2 shows in detail the receiving side corresponding to FIG.

FIG. 3 is a conventional configuration example, showing a transmitting side.

FIG. 4 is a conventional configuration example showing a receiving side.

[Explanation of Codes] NE1, NE2, JNE1, JNE2 Transmission-side terminal equipment NE5, NE6, JNE5, JNE6 Reception-side terminal equipment NE3, JNE4 Transmission-side wavelength multiplexing equipment NE4, JNE5 Reception-side wavelength multiplexing equipment C1 Signal switching unit C2 , C4, C24, JC2, JC4, JC7, JC2
3 electric-optical conversion units C6, C20, C25, JC6, JC22, JC18,
JC24 Optical-electrical converters C3, C19, JC3, JC17 Optical branching parts C5, C22, JC5, JC21 Wavelength converter C7 Block 1 C8 Block 2 C9, JC9 Optical wavelength multiplexer C10, C17, JC10, JC16 Optical amplifier C11 Connection management information generators C12, C16, C29, C31, JC11, JC1
4, JC27, JC28 Control / alarm monitoring section C13, C26, JC12, JC25 Photoelectric detection elements C14, C27, C30 Connection management information interpretation section C15, C28, JC13, JC26 Optical level monitoring section JC1 Connection management information insertion section JC19 Connection information Separators S1, S2, S4, S6, S23, S25, S27, J
S1, JS2, JS4, JS6, JS18, JS21,
JS23 Main signal (electricity) S3, S5, S7 to S11, S20 to S22, S24,
S26, S28, S29, JS3, JS5, JS7 to J
S11, JS15 to JS17, JS20, JS22, J
S24, JS25 Main signal (optical) S12, S18 False connection monitoring request S13, S14, S16, S19, S31, S33, S
34, JS12, JS27 Connection management information S15, S30, JS13, JS26 Optical level monitoring signals S17, S32, JS14, JS28 Optical level information

Claims (11)

(57) [Claims] 1. A transmitting side terminal device (NE1) and a transmitting side wavelength.
In the misconnection monitoring system of the optical wavelength division multiplexer, which is a backbone system apparatus configured to be connected to the multiplexer (NE3) , the transmission side terminal station equipment (NE1) generates connection management information different from the main signal. A connection management information generation unit of the functional unit, a first control / alarm monitoring unit (C12) that manages the connection management information generated by the connection management information generation unit with a device alarm, a device configuration, setting information, and the like. A signal switching unit (C1 ) that outputs the connection management information to the transmission side wavelength division multiplexer (NE3) instead of the main signal in response to an erroneous connection monitoring request that is an instruction from the first control / alarm monitoring unit (C12). ) And an optical branching unit (C3) for separating an optical input signal, and an optical branching unit (C3) for separating the optical input signal before the input unit of the transmission side wavelength division multiplexer (NE3) . Optical input signal to optical level Connection from the photoelectric detection element (C13), a photoelectric detection element (C13) that separates the optical supervisory signal and connection management information, an optical level monitoring unit (C15) that detects the optical power level from the optical level monitoring signal, A connection management information interpreting unit (C14) that interprets management information is further provided, and it is possible to monitor whether or not there is an erroneous connection and function maintenance for each component including a function unit, a wavelength signal unit , and various connection management information. An erroneous connection monitoring system for an optical wavelength multiplexer, which is characterized in that 2. The erroneous connection monitoring system for an optical wavelength division multiplexer according to claim 1, wherein the monitoring is performed when an erroneous connection monitoring is requested from the control / alarm monitoring unit (C12). 3. The optical wavelength division multiplexer according to claim 1, wherein the monitoring of the presence or absence of the erroneous connection is performed based on the connection management information from the connection management information interpretation unit (C14). Wrong connection monitoring system. 4. The optical wavelength division multiplexer according to claim 1, wherein the function maintenance is monitored based on the optical power level detected by the optical level monitor (C15). Misconnection monitoring system. 5. The erroneous connection monitoring system for an optical wavelength division multiplexer according to claim 3, further comprising a second control / alarm monitoring unit (C16) for performing the function maintenance monitoring. . 6. The optical wavelength division multiplexer includes a transmission side wavelength division multiplexer and a reception side wavelength division multiplexer, and monitors presence or absence of erroneous connection and function maintenance for each component.
The erroneous connection monitoring system for an optical wavelength division multiplexer according to claim 1, wherein the erroneous connection monitoring system is executable on both the transmitting side and the receiving side. 7. A transmission side terminal equipment (NE1) and a transmission side wavelength.
In the misconnection monitoring method for an optical wavelength division multiplexer of an optical wavelength division multiplexer, which is a backbone system apparatus configured to be connected with a multiplexer (NE3) , the transmission side terminal station equipment (NE1) is connected differently from a main signal. A connection management information generation step of a functional unit that generates management information; a control / alarm monitoring step of managing the connection management information generated in the connection management information generation step with a device alarm, a device configuration, setting information, and the like; The connection management information is sent in place of the main signal in response to an erroneous connection monitoring request which is an instruction from the control / alarm monitoring process
A signal switching step of outputting the signal to the receiving side wavelength division multiplexer (NE3) , and an optical branching step for separating an optical input signal before the input part of the transmission side wavelength division multiplexer (NE3) , and the optical branching step. A photoelectric detection step of separating an optical level monitoring signal and connection management information from the optical input signal separated by, an optical level monitoring step of detecting an optical power level from the optical level monitoring signal, and a connection from the photoelectric detection step. A connection management information interpretation step for interpreting management information is further provided, and it is possible to monitor whether or not there is an erroneous connection for each function unit including the function unit, the wavelength signal unit , and various connection management information and the function maintenance. A method for monitoring erroneous connection of an optical wavelength division multiplexer. 8. The erroneous connection monitoring method for an optical wavelength division multiplexer according to claim 7, wherein the monitoring is performed when an erroneous connection monitoring is requested from the control / alarm monitoring step. 9. The misconnection of the optical wavelength division multiplexer according to claim 7, wherein the presence or absence of the misconnection is monitored based on the connection management information from the connection management information interpretation step. Monitoring method. 10. The erroneous connection monitoring of the optical wavelength division multiplexer according to claim 7, wherein the function maintenance monitoring is performed based on the optical power level detected in the optical level monitoring step. Method. 11. The monitoring of the presence or absence of an erroneous connection and the maintenance of function for each of the functional units can be executed on both the transmitting side and the receiving side, according to any one of claims 7 to 10. An erroneous connection monitoring method for an optical wavelength division multiplexer according to any one of claims.