JPH01117433A - Optical cable system monitor system - Google Patents

Abstract

PURPOSE:To allow a terminal station to always monitor the state of a line or to easily locate a cable faulty section by receiving a burst signal sent from a terminal station in a relay connection section and applying frequency conversion, amplifying and sending the result back to the terminal station. CONSTITUTION:A since wave burst signal of a frequency fL sent from a land terminal station 10 is propagated sequentially relay connection sections 20, 30 and a signal subject to frequency conversion at each passing of a submarine optical repeater or a submarine optical cable joint box or the like, that is, a burst signal of frequency nfL to be generated is propagated toward the land terminal station 10, where the burst signal of frequency nfL is extracted by a high pass filter 13 and displayed on a CRT of a display device 14. Thus, a fault is surveyed for the submarine optical cable by using the burst signal displayed on the CRT.

Description

Detailed Description of the Invention [Field of Industrial Application] The present invention relates to an optical cable system monitoring method in optical cable communication using an optical cable, and particularly relates to an optical cable system monitoring method in optical cable communication using a pseudo-coaxial structure of an optical cable. .

[Conventional technology]

There are various types of submarine optical cables used in optical cable systems in optical cable communications, for example, submarine optical cable systems in submarine optical cable communications. For example, a deep-sea submarine optical cable having a cross-sectional structure as shown in FIG. 3 has recently been widely adopted. This submarine optical cable consists of an optical fiber unit 101, which is a normal component, and a three-part internal metal pipe 10.
2, tension member 103, and external metal pipe 10
4, an insulating polyethylene 105, an outer metal tape 106, and an outer polyethylene jacket 107. The metal tape 106 and the outer polyethylene jacket 107 are provided to protect the inside of the submarine optical cable from attacks by sharks and the like, or to protect the submarine optical cable from damage during installation.

As a monitoring method for monitoring a submarine optical cable system using such a submarine optical cable, the signal itself transmitted through the optical fiber unit 101 is modulated in some way, and the submarine optical repeater is controlled so as to be in-service or out-of-service. It is configured to receive information from a submarine optical repeater in the current state.

[Problem that the invention seeks to solve]

With the conventional submarine optical cable system monitoring method described above, it is possible to obtain various information such as the operating status of submarine repeaters and line characteristics, and although it is extremely useful for line operation, the configuration and operation are extremely complicated. The disadvantage is that it is not suitable for simple purposes such as locating cable cut points.

Incidentally, recent advances in submarine optical cable transmission technology have made it possible to increase the relay interval, and 1.55 μm band technology has enabled a relay interval of 100 to 150 km.

On the other hand, in the submarine optical cable itself, it is extremely difficult to manufacture a long cable of 1100 k or more as one continuous length. Therefore, one section of a long cable is
It is divided into three pieces, each of which is connected by a connection box called a joint box. In a system using such a submarine optical cable with a long repeat interval, there is a drawback that the fault location section is too long for one repeat section, and it is desirable to evaluate the fault location in a shorter section.

The purpose of the present invention is to eliminate such drawbacks and to provide a submarine optical cable system monitoring system that can easily investigate how far the cable is connected or in which section it has been cut in the event of a submarine optical cable failure in the submarine optical cable system. The goal is to provide a method.

[Means for solving problems]

The optical cable system monitoring method of the first invention is an optical cable system monitoring method for optical cable communication in which each optical cable having a pseudo-coaxial structure is relay-connected by a relay connection part and transmission is performed between terminal stations. , one of the terminal stations includes a signal generator that generates a burst signal having a first frequency; and a signal generator that passes the burst signal that has the first frequency from the signal generator and outputs it to the coaxial structure of the optical cable. a first filter that transmits a burst signal having a second frequency that has propagated through the coaxial structure of the optical cable; and a second filter that transmits a burst signal having a second frequency that is output from the second filter. display means for displaying a burst signal having a second frequency on a time axis, the relay connection section transmitting the first frequency that has been propagated from the terminal station through the coaxial structure of one optical cable. a third filter that amplifies the burst signal having the first frequency output from the third filter and outputs it to the coaxial structure of the other optical cable. a converter that generates a burst signal having a second frequency by a burst signal having a first frequency output from the first amplifier; a fourth filter that passes a burst signal having a frequency of , and a burst signal having a second frequency propagated from the coaxial structure of the other optical cable; and a second amplifier that amplifies a burst signal having a second frequency and outputs it to the coaxial structure of the one optical cable, and the one terminal station sends out the burst signal having the first frequency. Then, each relay connection unit sends this burst signal to the next relay connection unit, and at the same time generates a burst signal having a second frequency from this burst signal and sends it to the one terminal station. It is characterized by

The optical cable system monitoring method of the second invention is an optical cable system monitoring method for optical cable communication in which each optical cable having a pseudo-coaxial structure is relay-connected by a relay connection part and transmission is performed between terminal stations, One of the terminal stations includes a signal generator that generates a burst signal having a first frequency; and a signal generator that passes the burst signal that has the first frequency from the signal generator and outputs it to the coaxial structure of the optical cable. a first filter; a second filter that passes a burst signal having a second frequency that has propagated through the coaxial structure of the optical cable; and a second filter that is output from the second filter. a display means for displaying a burst signal having a second frequency on a time axis, and the other terminal station has a signal generator that generates a burst signal having a third frequency; , a third filter that passes a burst signal having a third frequency and outputs it to the coaxial structure of the optical fiber cable; and a third filter that passes a burst signal having a fourth frequency that has propagated through the coaxial structure of the optical cable. a fourth filter; and display means for displaying a burst signal having a fourth frequency outputted from the fourth filter on a time axis; a fifth filter that allows a burst signal having a first frequency and a burst signal having a fourth frequency to pass through the coaxial structure of the optical cable from the one terminal station; a sixth filter that allows a burst signal having a third frequency and a burst signal having a second frequency to pass through the coaxial structure of the optical cable from the other end station; The first filter outputted from the filter No.5. a burst signal having a fourth frequency, and a second . an amplifier for amplifying a burst signal having a third frequency; and a second burst signal output from the amplifier. Third
a seventh filter that passes a burst signal having a frequency and outputs it to the coaxial structure of the one optical cable, and filters a burst signal having a third frequency output from the seventh filter; a first converter that generates a burst signal having a frequency of 4 and outputs it to the fifth filter; an eighth filter that passes a burst signal having a fourth frequency and outputs it to the coaxial structure of the other optical cable; and a burst signal having the first frequency that is output from the eighth filter. generating a burst signal having a second frequency from the sixth
and a first converter that outputs the burst signal to the filter of the first frequency, and when the one terminal station sends out a burst signal having the first frequency, each relay connection unit transmits this burst signal to the next relay connection. At the same time, a burst signal having a second frequency is generated from the burst signal and transmitted to the one terminal station, and the other terminal station transmits a burst signal having a third frequency. Then, each relay connection unit sends this burst signal to the next relay connection unit, and at the same time generates a burst signal having a fourth frequency from this burst signal and sends it to the other terminal station. It is characterized by

〔Example〕

Next, embodiments of the present invention will be described with reference to the drawings.

The present invention is applied, for example, to a submarine optical cable system using a submarine optical cable. The submarine optical cable used in this submarine optical cable system has a pseudo-coaxial cable structure formed by an external metal pipe 104 and a metal tape 106 via an insulating polyethylene 105, as shown in FIG.

The present invention uses this pseudo coaxial structure to transmit electrical signals and monitor a submarine optical cable system.

FIG. 1 is a block diagram showing an embodiment of the first invention. This submarine optical cable system monitoring system consists of a land terminal station 10, a relay connection part 20 connected to the land terminal station 10 by a coaxial structure (hereinafter referred to as a line) 1 of the submarine optical cable, and a relay connection part 20 connected to the land terminal station 10 by a line 2. 20, and further connected to another relay connection section by a -path 3.

The land terminal station 10 includes a Z signal generator 11, a low-pass filter 12, a high-pass filter 13, and a display 14.

The signal generator 11 of the land terminal station 10 is a sine wave pursuit signal generator, and generates a sine wave burst signal of frequency fL.

A low pass filter 12 is coupled to the line 1 and injects the burst signal from the signal generator 11 into the line 1 .

The high-pass filter 13 is coupled to the line 1 and extracts a burst signal of frequency nfL propagating through the line 1.

The display 14 includes a CRT and displays the burst signal from the high-pass filter 13 on the time axis of the CRT.

The relay connection section 20.30 is provided in a submarine optical repeater or a submarine optical cable joint box that connects optical submarine cables. Furthermore, since the relay connecting sections 20 and 30 and other relay connecting sections have the same configuration and functions, only the relay connecting section 20 will be described here. Relay connection part 20
is composed of a bandpass filter 21.24, an amplifier 22.25, and a harmonic generation circuit 23.

The bandpass filter 21 of the relay connection section 20 passes the burst signal of frequency fL propagating through the line 1.

The amplifier 22 receives the frequency f output from the bandpass filter 21.
The L burst signal is amplified and output to the line 2 and simultaneously output to the harmonic generation circuit 23.

The harmonic generation circuit 23 receives the frequency fL from the amplifier 22.
When a burst signal is input, this signal is frequency-converted and a burst signal having a frequency nft higher than the frequency rL is output.

The bandpass filter 24 passes the burst signal of frequency nfL from the harmonic generation circuit 23. Further, the bandpass filter 24 passes the burst signal having the frequency nfL propagating through the line 2.

The amplifier 25 receives the frequency nfL from the bandpass filter 24.
The burst signal is amplified and injected into line 1.

Next, the operation of this embodiment will be described in the case of investigating a fault in a submarine optical cable or the like used in a submarine optical cable system.

A signal generator 11 of the land terminal station 10 generates a sine wave burst signal of frequency fL. This burst signal is coupled via a low-pass filter 12 to the central portion IA and outer peripheral portion IB of the line l. The central portion IA is an external metal vibrator 104 shown in FIG. 3, which is made of copper, aluminum, or the like, and is normally used as a power supply path for supplying direct current to a submarine optical repeater. The burst signal is superimposed on this DC current and sent to the line 1. The outer peripheral portion IB is the third
The metal tape 106 shown in the figure is made of aluminum or the like. As mentioned above, the center part IA and the outer peripheral part I
B is an imaginary coaxial cable structure, which serves as a good transmission path with low loss for sine wave burst signals of relatively low frequency. Now, the burst signal injected into line 1, which is the pseudo-coaxial structure, propagates through line l,
This leads to a submarine optical repeater or submarine optical cable joint box equipped with a relay connection section 20. Inside the relay connection section 20, after the voltage is stabilized by a DC current, a diode, etc., it is either shunted as a power source for the submarine optical repeater, or
Alternatively, in the case of a submarine optical cable joint box, it is simply bypassed by a zener diode (not shown in Figure 3). The superimposed sine wave burst signal is extracted by AC coupling and input to the amplifier 22 through the bandpass filter 21 that passes the frequency fL. The amplifier 22 amplifies the burst signal to a power level that is approximately equal to the line loss of the next section, and sends it to the next section line 2.

At the same time, a portion of the burst signal from the amplifier 22 is input to the harmonic generation circuit 23. The harmonic generation circuit 23 is
Frequency conversion is performed on the burst signal of frequency fL, and frequency nf is obtained.
Generates an L burst signal. The generated burst signal having a frequency of nfL passes through a bandpass filter 24 that passes only frequencies around the frequency nfL, and is input to an amplifier 25. The burst signal of frequency nft is amplified by the amplifier 25, coupled to the line 1, and propagated to the land terminal station 10.

On the other hand, as described above, the signal is output from the amplifier 22 and the line 2
The burst signal of frequency fL transmitted to the relay connection unit 30 via the relay connection unit 20 undergoes the same signal processing as the
It is processed. That is, this burst signal passes through a bandpass filter 31, is amplified by an amplifier 32, and is input to a harmonic generation circuit 33. Here, the burst signal of frequency fL is converted into a burst signal of frequency nft. This burst signal of frequency nfL passes through a bandpass filter 34, is amplified by an amplifier 35, and is injected into the line 2. This signal passes through the line 2 and is input to the relay connection section 20.

This burst signal of frequency nfL passes through a bandpass filter 24, is amplified by an amplifier 25, and is coupled to the line 1.
The signal is propagated to the land terminal station 10.

In this way, the sine wave burst signal of frequency fL sent from the land terminal station IO propagates sequentially through the relay connection, and each time it passes through a submarine optical repeater or submarine optical cable joint box, etc., the signal is converted into a frequency-converted signal. , that is, a burst signal of frequency nfL is generated. The generated burst signal of frequency nfL will be propagated toward the land terminal station 10. At the land terminal station 10, a high-pass filter 13 that passes the frequency nfL without passing the frequency fL extracts only the parsed signal having the frequency nfL, amplifies it if necessary, and displays it on the CRT of the display 14. indicate. FIG. 4 shows an example of a CRT display. The X-axis is the time axis, and the burst signal of frequency nfL is displayed which is received with a difference in time by the total time difference in which the burst signal of frequency fL propagates for one section and the burst signal of frequency nfL propagates in the opposite direction.

The burst signals displayed on the CRT can be used to investigate faults in submarine optical cables used in submarine optical cable systems.

The sine wave burst signal according to this embodiment has a small amplitude compared to the magnitude of the DC power supply current (approximately 1.5 to 2 A) to the submarine optical repeater, and is as large as possible without affecting the repeater operation. Set to amplitude. Therefore, it is clear that the monitoring according to this embodiment can be carried out in-service, and the condition of the line can be constantly monitored, and it can also be used for locating a faulty section when a cable is cut.

FIG. 2 is a block diagram showing an embodiment of the second invention. This submarine optical cable system monitoring system includes a land terminal station 40, a relay connection section 60 connected to the land terminal station 40 by a line 4, a relay connection section 70 connected to the relay connection section 60 by a line 5, Relay connection 7 via line 6
0 and a land terminal station 50 connected to the terminal station 50.

The land terminal station 40 includes a signal generator 41, a low-pass filter 42, a high-pass filter 43, and a display 44.

The signal generator 41 of the land terminal station 40 is a sine wave burst signal generator, and generates a sine wave burst signal of frequency fL.

The low-pass filter 42 passes the burst signal from the signal generator 41 and injects it into the line 4 .

The high-pass filter 43 filters the frequency nf that has propagated through the line 4.
Extract the L burst signal.

The display 44 includes a CRT and displays the burst signal from the high-pass filter 43 on the time axis of the CRT.

The land terminal station 50 includes a signal generator 51, a high-pass filter 52, a low-pass filter 53, and a display 54.

The signal generator 51 of the land terminal station 50 is a sine wave burst signal generator, and generates a sine wave burst signal of frequency fH.

The high-pass filter 52 passes the burst signal from the signal generator 51 and injects it into the line 6 .

The low-pass filter 53 filters the frequencies f, which have propagated through the line 6.
, /n burst signals are extracted.

The display 54 includes a CRT and displays the burst signal from the low-pass filter 53 on the time axis of the CRT.

The relay connection parts 60 and 70 are provided in submarine optical repeaters and submarine optical cable joint boxes that connect optical submarine cables. Furthermore, since the relay connection sections 60 and 70 have the same configuration and functions, only the relay connection section 60 will be described here. The relay connection section 60 is a low-pass filter 61.6.
5, high-pass filters 62 and 64, an amplifier 63, a frequency dividing circuit 66, and a harmonic generation circuit 67. In this way, in the relay connection section 60, the low-pass filter 61.6
5. The high-pass filters 62 and 64 and the common amplifier 63 are arranged as a well-known equivalent two-wire type amplifier, and the output of the low-pass filter 65 on the output side of the common amplifier is divided into two. One is directly connected to the next section, and the other is connected to the harmonic generation circuit 67. Similarly, the output of the high-pass filter 64 is divided into two parts, one being connected to the line 4 and the other being connected to the frequency dividing circuit 66.

The low-pass filter 61 of the relay connection section 60 passes the burst signal of frequency fL propagating through the line 4 and the burst signal of frequency f, . . . /n from the frequency dividing circuit 66.

The high-pass filter 62 filters the frequency f, which is propagated through the line 5.
and a burst signal of frequency nfL from the harmonic generation circuit 67 are passed.

Amplifier 63 receives frequency rL from low-pass filter 61 .

A burst signal of fN/n and a burst signal of frequency f, . . . nft from the high-pass filter 62 are amplified.

The high-pass filter 64 receives the frequency fH1n from the amplifier 63.
0 passed frequency nf that passes the burst signal of fL
The L burst signal propagates on line 4.

The frequency divider circuit 66 receives the frequency f from the high-pass filter 64 .

The burst signal is frequency-converted to generate a burst signal with a frequency f and a lower frequency fH/n, and is output to the low-pass filter 61.

A low-pass filter 65 receives the frequency fL from the amplifier 63.

The burst signals of f, , /n are passed. At this time, the burst signal of frequency fL is divided into two. One of the divided burst signals and the burst signal of frequency f, . . . /n propagate through the line 5.

The harmonic generation circuit 67 converts the frequency of the other divided burst signal of frequency fL from the low-pass filter 65, generates a burst signal of frequency nfL higher than frequency fL, and generates a burst signal of frequency nfL higher than frequency fL. The signal is output to the wave generator 62.

Next, the operation of this embodiment will be explained.

First, a case will be described in which the land terminal station 40 investigates a fault in a submarine optical cable or the like used in a submarine optical cable system.

A signal generator 41 of the land terminal station 40 generates a burst signal of frequency fL. This burst signal is filtered through a low-pass filter 4.
2 and is injected into line 4. The burst signal of frequency f that has propagated through the line 4 passes through the low-pass filter 61 of the relay connection section 60 and is input to the amplifier 63.

The burst signal of frequency fL output from amplifier 63 passes through low-pass filter 65. At this time, this burst signal is divided into two and output.

One of the two divided burst signals of frequency fL is frequency-converted by a harmonic generation circuit 67 to become a burst signal of frequency nfL. This burst signal passes through a high-pass filter 62 and is input to an amplifier 63. The burst signal of frequency nfl amplified by the amplifier 63 is passed through the high-pass filter 6
4 and is injected into line 4.

The other burst signal output from the low-pass filter 65 mentioned above is injected into the line 5. This burst signal of frequency rL propagates through the line 5 and is input to the relay connection section 70. Relay connection section 70 processes this burst signal similarly to relay connection section 60. That is, this burst signal is transmitted through the low-pass filter 71→amplifier 73→low-pass filter 7.
5 and undergoes frequency conversion by a harmonic generation circuit 77 to become a burst signal with a frequency nfL. This burst signal passes through a high-pass filter 72 - an amplifier 73 - a high-pass filter 74 and is injected into the line 5 . The burst signal of frequency nfL that has propagated through the line 5 is input to the relay connection section 60 .

Within the relay connection 60, this burst signal passes through a high-pass filter 62 - an amplifier 63 - a high-pass filter 64 and is injected into the line 4 .

In this way, the burst signal of frequency nfL from the relay connection 60.70 is input to the land terminal station 40.

This burst signal is extracted by the high-pass filter 43 of the land terminal station 40 and displayed on the CRT of the display 44. Accordingly, the land terminal station 40 can observe the burst signals of the frequency nfl in the order in which they arrive on the time axis.

Next, a case where a failure investigation is performed at the land terminal station 50 will be described. A signal generator 51 of the land terminal station 50 generates a burst signal of frequency rs. This burst signal passes through a high-pass filter 52 and is injected into the line 6'. The burst signal of frequency f, which has propagated through the line 6, is input to the relay connection section 70. Within the relay connection 70, this burst signal passes through a high-pass filter 72-amplifier 74 and passes through the high-pass filter 74.

At this time, this burst signal is divided into two and output.

One of the two divided burst signals with a frequency of "8" is frequency-converted by the frequency dividing circuit 76 to become a burst signal with a frequency of fH/n. This burst signal is passed through the low-pass filter 71-
The signal passes through the amplifier 73 → low-pass filter 75 and is injected into the line 6.

The other burst signal from the high-pass filter 74 mentioned above is injected into the line 5. These burst signals of frequencies f and l propagate through the line 5 and are input to the relay connection section 60 . Within the relay connection section 60, this burst signal passes through a high-pass filter 62 → amplifier 63 → high-pass filter 64, and is frequency-converted by a frequency dividing circuit 66 to become a burst signal with frequencies f and /n. Become. This burst signal passes through the low-pass filter 61 - amplifier 63 -> low-pass filter 65 and is injected into the line 5 .

The burst signal of frequency fH/n that has propagated through the line 5 is input to the relay connection section 70. Within the relay connection 70, this burst signal is passed through the low-pass filter 71-amplifier 73-
It passes through a low-pass filter 75 and is injected into the line 6.

In this way, the relay connection 60. A burst signal of frequency fH/n from To is input to the land terminal station 50. This burst signal is transmitted to the low-pass filter 5 of the land terminal station 50.
3 and displayed on the CRT of the display 54. Thereby, the land terminal station 50 can also observe the burst signal of frequency fH/n on the time axis.

In this way, it becomes possible to monitor the line and locate cable faults at both terminal stations.

As is clear from the above description, the amplifier, filter, etc. in the first invention only need to operate at a single frequency, and the amplifier in the second invention operates at frequencies fL,
Since it is sufficient to operate at four frequency points of f, , nfL, and fH/n, a simple circuit can be used.

〔Effect of the invention〕

As explained above, the present invention utilizes a pseudo coaxial structure composed of a metal tape and an internal metal pipe used to protect submarine optical cables as a signal transmission path, and uses it to connect submarine optical repeaters or Inside the submarine optical cable joint box, the burst signal sent from the terminal station is received and frequency converted.

By amplifying the signal and sending it back to the terminal station, it is possible to constantly monitor the line status at the terminal station, or to easily locate the faulty section in the event of a cable failure.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the first invention; FIG. 2 is a block diagram showing an embodiment of the second invention; FIG. 3 is a sectional view of a submarine optical cable having a pseudo-coaxial structure; FIG. 4 is a diagram showing an example of the display on the CRT of the terminal station. 1.2.3.4.5.6...Line IA...Central part 1B...Outer peripheral part 10, 40...Land terminal station 11, 41...Signal generator 12, 42 ...Low pass filter 13, 43...High pass filter 14, 44...Indicator 20, 30...Relay connection part 21.24.31.34... Bandpass filter 22
, 25.32.35...Amplifiers 23, 33.
...Harmonic generation circuit 60, 70...Relay connection section 61, 65.71.75...Low-pass filter 62
, 64.72.74...High-pass filter 63, 7
3... Amplifiers 66, 76... Frequency dividing circuits 67, 77... Harmonic generation circuit 50... Land terminal station 51... Signal generator 52... High frequency Filter 53...Low-pass filter 54...Display device agent Patent attorney Yoshiyuki Iwasa Figure 3 Figure 4

Claims (2)

[Claims] (1) An optical cable system monitoring method for optical cable communication in which each optical cable having a pseudo-coaxial structure is relay-connected by a relay connection part to transmit data between terminal stations, and one of the terminal stations is connected to a first terminal station. a signal generator that generates a burst signal having a frequency of; a first filter that passes the burst signal from the signal generator and outputs it to the coaxial structure of the optical cable; a second filter that passes the burst signal having a second frequency that has propagated through the coaxial structure of the optical cable; and a display means for displaying on the axis, and the relay connection part has a third coaxial structure of one optical cable that passes a burst signal having a first frequency propagated from the terminal station. a filter; a first amplifier that amplifies a burst signal having a first frequency output from the third filter and outputs it to the coaxial structure of the other optical cable; and the first amplifier. A burst signal having a first frequency output from
a converter that generates a burst signal having a second frequency; a burst signal having a second frequency from the converter; and a burst signal having a second frequency propagating from the coaxial structure of the other optical cable. a second filter that amplifies a burst signal having a second frequency outputted from the fourth filter and outputs it to the coaxial structure of the one optical cable. an amplifier, and when the one terminal station transmits a burst signal having a first frequency, each relay connection transmits this burst signal to the next relay connection and at the same time extracts from this burst signal. An optical cable system monitoring system characterized in that a burst signal having a second frequency is generated and sent to the one terminal station. (2) An optical cable system monitoring method for optical cable communication in which each optical cable having a pseudo-coaxial structure is relay-connected by a relay connection part to transmit data between terminal stations, and one of the terminal stations is connected to a first terminal station. a signal generator that generates a burst signal having a frequency of; a first filter that passes the burst signal from the signal generator and outputs it to the coaxial structure of the optical cable; a second filter that passes the burst signal having a second frequency that has propagated through the coaxial structure of the optical cable; display means for displaying on the axis; the other terminal station has a signal generator for generating a burst signal having a third frequency; and a burst signal having a third frequency from the signal generator. a third filter that passes through the burst signal and outputs it to the coaxial structure of the optical cable; a fourth filter that passes the burst signal having a fourth frequency that has propagated through the coaxial structure of the optical cable; display means for displaying a burst signal having a fourth frequency output from a fourth filter on a time axis, and the relay connection section connects the coaxial structure of one optical cable to the one a fifth filter that passes the burst signal having the first frequency and the burst signal having the fourth frequency propagated from the terminal station; a sixth filter that passes a burst signal having a third frequency and a burst signal having a second frequency propagated from the terminal station; and output from the fifth filter. , an amplifier that amplifies burst signals having first and fourth frequencies, and burst signals having second and third frequencies output from the sixth filter; and output from the amplifier. a seventh filter that passes burst signals having second and third frequencies and outputs them to the coaxial structure of the one optical cable; and a third frequency that is output from the seventh filter. generating a burst signal having a fourth frequency from a burst signal having a fourth frequency;
a first converter that outputs to the filter of the filter; and an eighth filter that passes the burst signals having the first and fourth frequencies output from the amplifier and outputs them to the coaxial structure of the other optical cable. generating a burst signal having a second frequency from the burst signal having the first frequency output from the eighth filter;
and a first converter that outputs the burst signal to the filter of the first frequency, and when the one terminal station sends out a burst signal having the first frequency, each relay connection unit transmits this burst signal to the next relay connection. At the same time, a burst signal having a second frequency is generated from the burst signal and transmitted to the one terminal station, and the other terminal station transmits a burst signal having a third frequency. Then, each relay connection unit sends this burst signal to the next relay connection unit, and at the same time generates a burst signal having a fourth frequency from this burst signal and sends it to the other terminal station. An optical cable system monitoring method characterized by: