JP2003060588A - Optical path monitoring apparatus and method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To directly detect abnormality with high accuracy on a transmission path in transmitting information by making an optical path to transmit monitoring signals. SOLUTION: A monitoring signal transmitting function is provided in a transmission side, and a monitoring signal receiving function is provided in a receiving side. Monitoring signals each consisting of one or multiple bits are periodically transmitted from the transmitting side, and these signals are received by the receiving side to monitor the abnormality of the optical path. The monitoring signal is composed of a field for indicating the total number of IP packets transmitted from the start to the end of monitoring or other information transmitting units, and a field for indicating a result of bit error detection calculation for the total IP packets transmitted from the start to the end of monitoring or other information transmitting units.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention is used in optical communication.
In particular, it relates to a technique for monitoring the normality of an optical path formed using an optical transmission line.

[0002]

2. Description of the Related Art A conventional optical path monitor will be described with reference to FIG. FIG. 7 is a conceptual diagram of an optical communication system for explaining a conventional optical path monitoring device. Reference numeral 40 is an optical reception level monitoring unit, 41 is an optical separation unit that separates an optical signal into the optical reception level monitoring unit, and 42 and 43 are optical cross-connects that have an optical path switch function.

Information is transmitted by forming an optical path between the optical cross connect 42 and the optical cross connect 43. The optical signal output from the optical cross connect 42 is distributed to the optical cross connect 43 and the optical reception level monitoring unit 40 through the optical transmission line 44 by the receiving side optical sorting unit 41.
The optical reception level monitoring unit 40 constantly monitors the reception level of the optical signal from the optical sorting unit 41, and when it becomes a certain level or less, judges that there is an abnormality in the optical transmission line 44 and issues an alarm.

Further, the optical cross connects 42 and 43
Can be realized by using a micromirror or the like (Nikkei Electronics (2001.1.29)).

[0005]

In optical communication for transmitting an optical signal by forming an optical path using an optical transmission line,
Conventionally, whether or not an optical signal is normally transmitted by an optical path has been determined by monitoring the presence or absence of an optical signal on the transmission and the optical reception level. Therefore, a partial failure such as a bit error could not be detected. That is, as shown in FIG. 7, since the failure detection is performed by detecting the light reception level, it is difficult to detect a temporary unstable state of the transmission signal such as a bit error.

The present invention has been made under such a background, and by transmitting a supervisory signal to an optical path,
An object of the present invention is to provide an optical path monitoring device and method capable of detecting with high accuracy whether or not there is any abnormality in directly transmitting information through a transmission path.

That is, according to the present invention, when neither the information frame nor the supervisory signal arrives for a certain period, it can be determined that there is a fatal failure in the transmission path, and the information frames for all the information frames in the supervisory period can be detected. It is possible to monitor faults with high performance such as disappearance and bit error, it is possible to easily distinguish the information frame and the supervisory signal, and because the information frame is transmitted with priority over the supervisory signal, the supervisory signal adversely affects the information transmission. It is an object of the present invention to provide an optical path monitoring device and method that does not exceed the above.

[0008]

The present invention provides a supervisory signal transmitting function on the transmitting side and a supervisory signal receiving function on the receiving side when an optical path is formed using an optical transmission line to transmit information.
The main feature is that the transmitting side periodically transmits a supervisory signal composed of one or more bits, and the receiving side receives the supervisory signal to monitor the normality of the optical path.

At the transmitting side, when the supervisory signal is transmitted, if the optical path is being used for information transmission, the supervisory signal is stopped from being transmitted, and if the optical path is not being used, the supervisory signal is transmitted and the receiving side Then, at the time of receiving the supervisory signal, if the optical path is being used for information transfer, the monitoring by the supervisory signal is stopped, and if the optical path is not being used for information transfer, the supervisory signal is monitored. Characterize.

Further, the supervisory signal has at least a specific 8-bit pattern, an identification field for identifying the supervisory signal, and the IP transmitted from the start to the end of the surveillance.
It is characterized by including a total number display field of information transmission units such as packets and a field showing a bit error detection calculation result for all information transmission units such as IP packets transmitted from the start to the end of monitoring. .

That is, a first aspect of the present invention is an optical path monitoring apparatus having means for monitoring the status of a failure of an optical path formed by using an optical transmission line, which is a feature of the present invention. However, the means for monitoring includes means for periodically transmitting the monitoring signal from one end of the monitored optical path, means for receiving the monitoring signal from the other end of the monitored optical path, and means for receiving the monitoring signal. And a first detecting means for detecting the occurrence of a failure including the disconnection status of the monitored optical path by determining whether or not the monitoring signal has been received.
Accordingly, by transmitting the monitoring signal to the optical path, it is possible to directly detect with high accuracy whether or not there is any abnormality in the transmission path transmitting information.

Further, means for recording the status of the information frame transmitted to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle,
Means for writing the status of the information frame recorded by the recording means in the supervisory signal transmitted in the next supervisory signal transmission cycle; and the means for writing in the supervisory signal received by the receiving means. It is preferable to provide a second detecting means for detecting a signal error of the monitored optical path or a failure occurrence including a loss status of the information frame by reading the status of the information frame.

The recording means counts the number of information frames sent to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle, and the last supervisory signal transmission. And a transmission error calculation means for further calculating an error check calculation bit of the information frame sent to the monitored optical path in the period from the cycle to the next supervisory signal transmission cycle. It is desirable to have means for writing the counting result of the means for counting the number of information frames and the calculation result of the transmission error calculating means into the monitoring signal.

Further, means for counting the number of information frames received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle,
A second error detection means for further calculating an error check operation bit of the information frame received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle. The loss in the period by comparing the count result of the means for counting the number of received information frames with the count result of the means for counting the number of transmitted information frames written in the supervisory signal. Means for detecting the number of information frames, and means for detecting a signal error in the period by comparing the calculation result of the reception error calculation means with the calculation result of the transmission error calculation means written in the monitoring signal. It is desirable to have and.

Thus, when neither the information frame nor the supervisory signal arrives for a certain period, it can be judged that there is a fatal failure in the transmission line, and the disappearance of the information frame or the bit for all the information frames in the surveillance period. It is possible to monitor faults with high performance such as errors.

The means for transmitting comprises means for stopping the transmission of the supervisory signal when the timing at which the information frame is sent to the monitored optical path and the transmission timing of the supervisory signal overlap, and the means for receiving the signal is received. It is preferable that the means includes means for stopping the monitoring by the monitoring signal when the timing at which the information frame is received from the monitored optical path and the reception timing of the monitoring signal overlap. As a result, it is possible to control the monitoring signal used for monitoring so as not to adversely affect normal information transmission.

It is preferable that the supervisory signal has an identification field indicating that the supervisory signal is the supervisory signal. As a result, it is possible to easily distinguish the information frame from the supervisory signal, and it is possible to easily realize control so that the supervisory signal does not adversely affect normal information transmission.

A second aspect of the present invention is an optical path monitoring method for monitoring a fault condition of an optical path formed by using an optical transmission line, which is a feature of the present invention. A supervisory signal is periodically transmitted from one end of the path, the supervisory signal is received from the other end of the monitored optical path, and it is determined whether or not the supervisory signal can be received, thereby connecting the monitored optical path. It is in the process of detecting the occurrence of a failure including the disconnection status.

Further, the status of the information frame transmitted to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle is recorded, and the status of the recorded information frame is recorded next time. Signal state of the monitored optical path or loss state of the information frame by writing to the supervisory signal transmitted in the supervisory signal transmission cycle and reading the state of the information frame written in the received supervisory signal It is possible to detect the occurrence of a failure including.

The number of information frames transmitted to the monitored optical path during the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle is counted, and the number of information frames sent from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle is counted. It is desirable to further calculate the error check operation bit of the information frame sent to the monitored optical path in the period up to and to write the counting result and the operation result in the monitoring signal.

Further, the number of information frames received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle is counted, and the next supervisory signal reception from the last supervisory signal reception cycle is counted. The error check calculation bit of the information frame received from the monitored optical path during the period up to the cycle is further calculated, and the counting result of the number of the received information frames is compared with the counting result written in the monitoring signal. By detecting the number of lost information frames in the period, by comparing the operation result of further operating the error check operation bit of the received information frame with the operation result written in the monitoring signal, It is desirable to detect signal errors during the period.

When the timing at which the information frame is transmitted to the monitored optical path and the timing at which the monitoring signal is transmitted overlap, the transmission of the monitoring signal is stopped, and the information frame is received from the monitored optical path. It is desirable to stop the monitoring by the monitoring signal when the timing when the monitoring signal and the reception timing of the monitoring signal overlap.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical path monitoring apparatus according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a system configuration diagram for explaining the first embodiment of the present invention. FIG. 2 is a diagram showing transmission of information frames. FIG. 3 is a diagram showing a transmission time relationship between an information frame and a supervisory signal. FIG. 4 is a diagram showing a configuration example of an information frame. FIG. 5 is a diagram showing a configuration example of the supervisory signal. FIG. 6 is a system configuration diagram for explaining the third embodiment of the present invention.

The present invention is an optical path monitoring apparatus for monitoring a failure condition of an optical path formed by using an optical transmission line,
The feature of the present invention is that, as shown in FIG. 1, a monitoring signal generator 4 that periodically transmits a monitoring signal from one end of the monitored optical path, and the monitoring signal from the other end of the monitored optical path. And a supervisory signal test unit 7 for detecting the occurrence of a failure including the disconnection status of the monitored optical path by determining whether or not the supervisory signal has been received. It is in.

Further, as shown in FIG. 6, a transmission counter section 8 for recording the condition of the information frame transmitted to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle, and A transmission error calculator 9;
The supervisory signal inserting unit 5 writes the status of the recorded information frame in the supervisory signal transmitted in the next supervisory signal transmission cycle, and the supervisory signal test unit 7-1 is configured to detect the supervisory signal received. By reading the status of the information frame written in, it is possible to detect a fault occurrence including a signal error of the monitored optical path or a loss status of the information frame.

The transmission counter section 8 counts the number of information frames sent to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle, and the transmission error computing section 9 The error check calculation bit of the information frame transmitted to the monitored optical path in the period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle is further calculated, and the supervisory signal insertion unit 5 of the transmission counter unit 8 The counting result and the calculation result of the transmission error calculating section 9 are written in the monitoring signal.

The reception counter unit 10 counts the number of information frames received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle, and the reception error calculation unit 11 Of the information frame received from the monitored optical path in the period from the supervisory signal reception cycle to the next supervisory signal reception cycle, the supervisory signal test unit 7-1 of the supervisory signal test unit 7-1 The number of lost information frames in the period is detected by comparing the count result with the count result of the transmission counter unit 8 written in the monitor signal, and the calculation result of the reception error calculator 11 and the monitor signal are written. The signal error in the above period is detected by comparing the calculated operation result of the transmission error operation unit 9.

The supervisory signal generator 4 stops the transmission of the supervisory signal when the timing at which the information frame is sent to the monitored optical path and the transmission timing of the supervisory signal overlap, and the supervisory signal tester 7 Stops monitoring by the monitoring signal when the timing at which the information frame is received from the monitored optical path and the timing at which the monitoring signal is received overlap.

The supervisory signal, as shown in FIG. 5, is provided with an identification field 35 indicating that it is the supervisory signal.

The embodiments of the present invention will be described in more detail below.

(First Embodiment) A first embodiment of the present invention will be described with reference to FIGS. 1 and 2. FIG. 1 is a system configuration diagram of an optical path monitoring apparatus according to an embodiment of the present invention, in which 1 is an information signal path on the transmitting side, 2 is an optical transmission path, 3 is an information signal path on the receiving side, and 4 is a supervisory signal generation. Reference numeral 5 denotes a supervisory signal inserting unit for transmitting a supervisory signal to the optical transmission line 2, 6 a supervisory signal branching unit for splitting the supervisory signal from the optical transmission line 2, and 7 a supervisory signal test unit.

Information is transmitted in units of a certain unit called an information frame as shown in FIG. 2 through the signal paths 1 and 3 and the transmission path 2. An operation example of the embodiment of the present invention will be described with reference to FIGS. 1 and 2. Normally, the information frame is transmitted from the signal line 1 to the signal line 3 via the transmission line 2. The supervisory signal generator 4 periodically generates a supervisory signal. At the timing of transmitting the supervisory signal, the supervisory signal generator 4 generates a supervisory signal, and the supervisory signal inserter 5 sends the supervisory signal to the transmission line 2. Sent. On the receiving side, the supervisory signal branching unit 6 detects the supervisory signal and sends it to the supervisory signal testing unit 7.

The supervisory signal test section 7 checks the signal included in the supervisory signal to test whether the supervisory signal is correctly received. If it is received correctly, it means that the transmission line is normal, and if it is wrong, it means that the transmission line is abnormal.

As described above, by transmitting a supervisory signal through the optical path instead of the conventional indirect method of measuring an optical reception level to detect an abnormality, it is possible that the transmission path directly transmits an abnormality. There is an effect that can detect whether there is no.

(Second Embodiment) A second embodiment of the present invention will be described with reference to FIG. FIG. 3 shows a transmission time relationship between an information frame and a supervisory signal for explaining the second embodiment of the present invention. 20-n are information frames, 21-1, 21-2, ..., 21-n are supervisory signals. Information frames 20-1, 20-1, ..., 2
0-n is transmitted irregularly. On the other hand, the monitoring signal 21-
, 21-2, ..., 21-n occur at a constant cycle. Now, as shown in FIG. 3, when the transmission of the information frame 20-1 and the transmission timing of the supervisory signal 21-1 overlap, the supervisory signal 21-1 stops transmitting.

At the transmission timing of the monitor signal 21-2,
Since the information frame is not transmitted, the supervisory signal 21-
2 is transmitted on the transmission path. That is, it means that the information frame is preferentially transmitted even at the supervisory signal transmission timing. On the receiving side, even at the supervisory signal reception timing, the supervisory operation by the supervisory signal is not performed unless a signal indicating the supervisory signal comes.

That is, the present invention has the effect that the supervisory signal does not adversely affect the information transmission. Also, for a certain period,
When neither the information frame nor the supervisory signal comes, it can be determined that there is a fatal abnormality in the transmission path.

(Third Embodiment) A third embodiment of the present invention will be described with reference to FIGS. FIG. 4 shows the structure of an information frame for explaining the third embodiment of the present invention.
Is a fixed pattern of 8 bits, 31 is an identification field indicating an information frame, 32 is information content to be transmitted, and 33 is a signal error check operation bit.

FIG. 5 shows the configuration of the supervisory signal according to the third embodiment of the present invention, in which 34 is a fixed pattern of 8 bits and 3
5 is an identification field indicating that it is an information frame, 3
6 is a count field indicating the number of counts of the information frames sent from the last supervisory signal transmission to this time's supervisory signal transmission, 37 is each information frame transmitted from the last supervisory signal's transmission to this time's supervisory signal transmission An operation result field showing the result of further operation of the error check operation bit, and 38 is a signal error check operation bit of the supervisory signal.

FIG. 6 is a system block diagram for explaining the third embodiment of the present invention, in which 8 is a transmission counter section for counting the number of information frames transmitted during the monitoring period,
Reference numeral 9 is a transmission error calculation unit that further calculates the error check calculation bit of each information frame sent during the monitoring period, 10 is a reception counter unit that counts the number of information frames received during the monitoring period, and 11 is received during the monitoring period. The reception error calculation unit 7-1 further calculates the error check calculation bit of each information frame, and 7-1 indicates to the supervisory signal test unit 7 the reception contents of the supervisory signal, the reception counter unit 10 and the reception error arithmetic unit 11.
This is a supervisory signal test unit with a function of comparison and inspection with the output of.

First, immediately after the transmission of the supervisory signal, the counter of the transmission counter section 8 and the calculation result of the transmission error calculation section 9 are cleared. Next, each time an information frame is sent out, it is counted by the counter of the transmission counter unit 8 and calculated by the transmission error calculation unit 9. Also on the receiving side, the counter of the reception counter unit 10 and the calculation result of the reception error calculation unit 11 are cleared immediately after receiving and testing the supervisory signal. Next, each time an information frame is received, it is counted by the counter of the reception counter unit 10 and calculated by the reception error calculation unit 11. On the receiving side, the information frame identification field 31 and the supervisory signal identification field 35 are viewed to identify whether it is an information frame or a supervisory signal. If it is a supervisory signal, the supervisory signal test unit 7-1
Check the count field 36 and the result of the reception counter section 10 to see if they match the number of received information frames. . In addition, the calculation result field 37 of the received supervisory signal and the reception error calculation unit 1
When the result of No. 1 is collated and they match, it is determined that there was no transmission error such as a bit error during the monitoring period.

As described above, according to the present invention, it is possible to easily distinguish the information frame from the supervisory signal, and further, it is possible to monitor the signal error and the information frame loss for all the information frames in the supervisory period. is there.

[0043]

As described above, according to the present invention,
By transmitting the monitoring signal to the optical path, it is possible to directly detect with high accuracy whether or not there is any abnormality in the transmission path transmitting information. That is, when neither the information frame nor the supervisory signal comes for a certain period of time, it can be determined that there is a fatal failure in the transmission line, and the disappearance of the information frame and the bit error for all the information frames in the surveillance period are high. The performance fault can be monitored, the information frame and the supervisory signal can be easily distinguished, and the supervisory signal does not adversely affect the information transmission because the supervisory signal is transmitted with priority given to the supervisory signal.

[Brief description of drawings]

FIG. 1 is a system configuration diagram for explaining a first embodiment of the present invention.

FIG. 2 is a diagram showing transmission of an information frame.

FIG. 3 is a diagram showing a transmission time relationship between an information frame and a supervisory signal.

FIG. 4 is a diagram showing a configuration example of an information frame.

FIG. 5 is a diagram showing a configuration example of a supervisory signal.

FIG. 6 is a system configuration diagram for explaining a third embodiment of the present invention.

FIG. 7 is a system configuration diagram for explaining a conventional optical path monitoring method.

[Explanation of symbols]

1, 3 information signal path 2,44 optical transmission line 4 Monitoring signal generator 5 Monitoring signal insertion section 6 Monitoring signal branch 7, 7-1 Supervisory signal test unit 8 Transmission counter section 9 Transmission error calculator 10 Reception counter section 11 Reception error calculator 20-1 to 20-n information frame 21-1 to 21-n Supervisory signal 30, 34 fixed pattern 31, 35 Identification field 32 Information content to be transmitted 33, 38 Signal error check operation bit 36 count field 37 Operation result field 40 Optical reception level monitor 41 Light sorting section 42,43 Optical cross connect

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04L 29/14 H04L 13/00 313 F term (reference) 5K002 DA03 EA06 FA01 GA03 5K030 JA10 JA12 JL03 MB05 MB09 MB12 MC03 MC07 5K035 AA03 BB01 DD01 EE10 JJ01 JJ05 5K042 BA14 CA10 DA17 DA18 DA27 EA06 GA02 HA13

Claims (11)

[Claims] 1. An optical path monitoring apparatus comprising means for monitoring a fault condition of an optical path formed by using an optical transmission line, wherein the monitoring means periodically monitors a monitoring signal from one end of the monitored optical path. Means for transmitting the monitored signal from the other end of the monitored optical path, and means for receiving the monitored signal by the receiving means to determine whether the monitored optical path An optical path monitoring device comprising: a first detection unit that detects a failure occurrence including a disconnection state. 2. A means for recording the status of the information frame transmitted to the monitored optical path in the period from the previous supervisory signal transmission cycle to the next supervisory signal transmission cycle, and the means for recording by the recording means. Means for writing the status of the information frame in the supervisory signal transmitted in the next supervisory signal transmission cycle, and reading the status of the information frame written in the supervisory signal received by the means for receiving The optical path monitoring device according to claim 1, further comprising a second detection unit that detects a signal error of the monitored optical path or a failure occurrence including a loss situation of the information frame. 3. The means for recording includes means for counting the number of information frames transmitted to the monitored optical path in a period from the last supervisory signal transmission cycle to the next supervisory signal transmission cycle; Transmission error calculation means for further calculating an error check calculation bit of the information frame transmitted to the monitored optical path in the period from the signal transmission cycle to the next monitoring signal transmission cycle, wherein the writing means is the transmission means. 3. The optical path monitoring device according to claim 2, further comprising means for writing the counting result of the counting means for counting the number of information frames and the calculation result of the transmission error calculating means into the monitoring signal. 4. A means for counting the number of information frames received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle, and the next supervisory signal from the last supervisory signal reception cycle. And a reception error calculation unit that further calculates an error check calculation bit of the information frame received from the monitored optical path in a period up to a signal reception cycle, wherein the second detection unit determines the number of the received information frames. Means for detecting the number of lost information frames in the period by comparing the counting result of the counting means and the counting result of the means for counting the number of the transmitted information frames written in the supervisory signal; By comparing the calculation result of the reception error calculation means with the calculation result of the transmission error calculation means written in the supervisory signal, Optical path monitoring apparatus according to claim 2, further comprising a means for detecting a signal error between. 5. The means for transmitting comprises means for stopping transmission of the supervisory signal when the timing at which an information frame is transmitted to the monitored optical path and the transmission timing of the supervisory signal overlap, The optical path according to claim 1, wherein the means for receiving includes means for stopping monitoring by the monitoring signal when the timing at which the information frame is received from the monitored optical path and the timing for receiving the monitoring signal overlap. Monitoring equipment. 6. The optical path monitoring device according to claim 1, wherein the supervisory signal includes an identification field indicating that the supervisory signal is a supervisory signal. 7. An optical path monitoring method for monitoring a fault condition of an optical path formed by using an optical transmission line, wherein a monitoring signal is periodically transmitted from one end of the monitored optical path, The optical path monitoring method, wherein the failure occurrence including the disconnection status of the monitored optical path is detected by receiving the monitoring signal from the other end of the optical path and determining whether or not the monitoring signal can be received. . 8. The status of the information frame transmitted to the monitored optical path in the period from the previous supervisory signal transmission cycle to the next supervisory signal transmission cycle is recorded, and the status of the recorded information frame is recorded next time. Signal state of the monitored optical path or loss state of the information frame by writing to the supervisory signal transmitted in the supervisory signal transmission cycle and reading the state of the information frame written in the received supervisory signal The optical path monitoring method according to claim 7, wherein the occurrence of a failure including the above is detected. 9. The number of information frames transmitted to the monitored optical path in the period from the previous supervisory signal transmission cycle to the next supervisory signal transmission cycle is counted, and the previous supervisory signal transmission cycle to the next supervisory signal is counted. 9. The optical path monitoring method according to claim 8, wherein an error check calculation bit of the information frame transmitted to the monitored optical path during the period up to the transmission cycle is further calculated, and the counting result and the calculation result are written in the monitoring signal. . 10. The number of information frames received from the monitored optical path in the period from the last supervisory signal reception cycle to the next supervisory signal reception cycle is counted, and the next supervisory signal reception from the last supervisory signal reception cycle is counted. The error check calculation bit of the information frame received from the monitored optical path during the period up to the cycle is further calculated, and the count result of the number of the received information frames is compared with the count result written in the monitor signal. By detecting the number of lost information frames in the period, by comparing the operation result further operation of the error check operation bit of the received information frame and the operation result written in the supervisory signal 9. The optical path monitoring method according to claim 8, wherein a signal error during the period is detected. 11. The transmission of the supervisory signal is stopped when the timing of transmission of the information frame to the monitored optical path and the timing of transmission of the supervisory signal overlap, and an information frame is received from the monitored optical path. 8. The optical path monitoring method according to claim 7, wherein the monitoring by the monitoring signal is stopped when the current timing and the reception timing of the monitoring signal overlap.