JP3166956B2 - Digital relay transmission system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used for an optical repeater of a digital repeater transmission system. In particular, CCITT G.707, G.708, G.
The present invention relates to a monitoring apparatus for an optical repeater inserted in a transmission line of a digital relay transmission system having a redundant configuration conforming to 709.

[0002]

2. Description of the Related Art FIG. 11 is a block diagram of a digital relay transmission system. FIG. 12 is a diagram showing the structure of an STM frame of the digital relay transmission system. FIG. 13 is a switching sequence diagram showing the switching operation of the digital relay transmission system. FIG. 14 is a diagram showing the definition of the K1 byte of the multiple section overhead of the digital relay transmission system. FIG. 15 is a diagram showing the definition of the K2 byte of the multiple section overhead of the digital relay transmission system. FIG. 16 is a block diagram of a conventional digital relay transmission system redundant configuration.

In FIG. 11, a plurality of low-speed optical signals are converted into high-speed optical signals by a multiplexing terminal equipment (LT-MUX) 10 and transmitted. The high-speed optical signal after transmission is separated again by the multiplexing terminal device 10 into a plurality of low-speed optical signals.
The high-speed optical signal output from the multiplexing terminal device 10 receives various kinds of interference (attenuation, waveform distortion, noise, etc.) from the optical fiber.
Receive. An optical repeater (REP) 20 is used to remove these and increase the distance between the multiplexing terminal devices 10.

The optical repeater 20 includes an optical regenerative repeater (3R-RE)
P) and optical linear repeater (1R-REP). The optical regenerative repeater has functions of optical-electric conversion, electric-optical conversion, equivalent amplification, retiming extraction, and identification reproduction. The optical signal that has been attenuated and distorted by being transmitted through the optical fiber is reproduced and output by the function of an optical regenerator.
The optical linear repeater has a function of amplifying an optical signal as it is, and compensates only for attenuation of the optical signal caused by being transmitted in an optical fiber (for example, Hagimoto, Aoyama: Relay using an optical fiber amplifier). Transmission system, IEICE Transactions B-1, Vol.75-B-1, No.5, p246, 1992). Optical regenerative repeaters have been introduced into commercial systems, but optical linear repeaters are still under research and development.

In accordance with the new synchronous interface recommended by the International Telegraph and Telephone Consultative Committee (CCITT), Nippon Telegraph and Telephone Corporation (NTT) has introduced a synchronous digital hierarchy transmission system (SDH transmission system) since 1989.

Conventionally, a digital relay transmission system is shown in FIG.
As shown in FIG. 11, the configuration shown in FIG.
0 ₁ , 10 ₂ and the optical regenerator 24.
In the digital relay transmission system, both the low-speed optical signal and the high-speed optical signal are synchronous transfer mode frames (hereinafter, referred to as "frames") shown in FIG.
This is called an STM frame. ) To enhance the monitoring function and improve the reliability of the system. The STM frame is characterized by having an operation and maintenance information area (section overhead, S-OH) corresponding to about 10% of the transmission speed. Section overhead can be classified into regenerator section overhead (RS-OH), pointer, and multiple section overhead (MS-OH). The regenerator section overhead is the optical regenerator 24
The multiplexing terminal devices 10 ₁ and 10 ₂ are used for performing frame synchronization, error monitoring, and the like. The multiple section overhead is the multiplexed terminal equipment 10 ₁ , 10
₂ is used to perform system redundancy switching, error monitoring, etc. The optical regenerator 24 processes the upper three lines (regenerator section overhead) of the section overhead in the STM frame, and the multiplexing terminal equipment 10 ₁ ,
10 ₂ In STM frame section 9 rows all overhead (regenerator section overhead, pointer, multiple section overhead) will process.

In the configuration shown in FIG. 16, service disconnection may occur due to cable disconnection or failure of the optical regenerator 24. In the digital relay transmission system of the synchronous digital hierarchy, the multiplexing terminal equipment 1 is used to improve reliability.
There is a redundant transmission line between 0 ₁ and 10 ₂ . As a result, when a service interruption or service quality deterioration is detected,
Can be switched automatically. This is called system switching. The system of the backup transmission line 1 for the used transmission line 1 is called 1: 1 and the system of the backup transmission line 1 for the used transmission line N is called N: 1. FIG. 16 shows a configuration example of 1: 1.

[0008] CCITT G.783 specifies switching of a synchronous digital hierarchy transmission system based on K1 and K2 bytes of multiple section overhead. FIGS. 14 and 15 show bit assignments of the K1 byte and the K2 byte of the multiple section overhead specified by CCITT G.783. Each of the K1 byte and the K2 byte is 8 bits, and the first bit is represented by b1, and the second bit is represented by b2. CCITT G.78
3 considers a 1: 1 or N: 1 redundant system with switchback and a 1: 1 redundant system without switchback. here,
When the used transmission line fails and switches to the spare transmission line, and the used transmission line is restored, the switching is performed again. This is called switching back.
Further, even if the used transmission path has failed and switched to the spare transmission path, the switching is not performed again even if the used transmission path has been restored. This is called switching without switching back.

[0009] In the case of switching without switching back, the transmission path that was spare after the switching will continue to be used for providing services. If the transmission line that provides the service is called [working], in the case of switching without switching back, the [working] transmission line is changed after the switching. For this reason, the meaning of the K2 byte is slightly different between switching with switching back and switching without switching back. In the case of switching with switching back, the K2 byte indicates the number of the transmission line connected to [spare]. In the case of switching without switching back, the K2 byte indicates the number of the [working] transmission path.

Referring to FIG. 16, an example of switching of the 1: 1 redundant system without switching back of the digital relay transmission system will be described. The digital relay transmission system shown in FIG. 16 is a 1: 1 redundant system, and a transmission line having a transmission line number of “1” (hereinafter, a transmission line of “1”) is provided between the multiplexing terminal devices 10 ₁ and 10 _2. ) And a transmission line with a transmission line number of “2” (hereinafter, referred to as a “2” transmission line).

In the steady state, both multiplexing terminal devices 10 ₁ ,
10 ₂ notifies [no switching request]. The multiplexing terminal device 10 ₁ transmits the same signal on the downlink of the “1” transmission line and the “2” transmission line, and the multiplexing terminal device 10 ₂ first selects the “1” transmission line. are doing. Multiplexing terminal device 10
At _2, when detecting an error detection or transmission path disconnection from downlink transmission path "1", and notifies the "switching request" using uplink multiplexing terminal station apparatus 10 _1. Multiplexing terminal device 10
₁ After confirming the "switching request", the switching to the transmission path of the selector of the device itself "2", and notifies the "switching response" to the multiplexing terminal station apparatus 10 _2. Multiplexing terminal station apparatus 10 _2, after receiving the notified from the multiplexing terminal station apparatus 10 ₁ "switch response",
The selector of the own device is switched from the transmission line of “1” to the transmission line of “2”. When error detection or transmission path disconnection at multiplexer terminal station apparatus 10 ₂ is restored, multiplex terminal station apparatus 10 ₂ notifies the "recovery standby" to multiplexer terminal apparatus 10 _1. Both multiplexing terminal devices 10 ₁ and 10 ₂ confirm the line normal state for a certain period of time and notify each other of “no switching request”.

[0012]

However, in such a conventional digital relay transmission system, when a multiplexing terminal station and an optical regenerative repeater are used, system switching is performed by the multiplexing terminal station. The device uses the K1 and K2 bytes of the multiple section overhead. The multiplexing terminal device knows the use state of the transmission path because it switches the selector by itself. For this reason, a package related to the used transmission path can be notified to a maintenance person or a monitoring system. For example, an ACT lamp indicating that the package is related to the used transmission path is mounted on each package and turned on, so that a maintenance person can be notified of the use state of the device. When maintaining the multiplexed terminal device, the maintenance person can replace the package whose ACT lamp is not lit even during the service.

On the other hand, in the optical regenerative repeater, it was not known whether the transmission line was used or not currently used because of the spare transmission line. If the optical regenerative repeater is not currently used because of the backup transmission line, maintenance can be performed. However, if maintenance work is performed on the optical regenerative repeater using the transmission line, there is a possibility that the service will be cut off. For this reason, in a station where an optical regenerator is installed, the maintenance person must use the multiplexed terminal equipment at the station where the multiplexed terminal equipment is installed when performing package switching or resetting of line control items. There was a problem that had to be checked.

The conventional digital repeater transmission system does not use an optical linear repeater. It is expected that a digital repeater transmission system using an optical linear repeater will be introduced in the future. Between multiplexing terminal equipment, or between optical regenerators,
Alternatively, a digital relay transmission system using an optical linear repeater between the multiplexing terminal device and the optical regenerator is conceivable. Similarly to the optical regenerative repeater described above, it is not known whether the optical linear repeater uses a transmission line or is not currently used because of a spare transmission line. For this reason, as in the case of the optical regenerative repeater, in the station where the optical linear repeater is installed, when the maintenance person performs package replacement or resetting of the line control items, the station in which the multiplex terminal equipment is installed is called There is a problem that the use state of the optical linear repeater must be checked.

Since the optical linear repeater is an analog optical amplifier, it monitors input optical power, output optical power, noise figure, current consumption of internal elements, etc. for self-diagnosis and fault evaluation. When a monitor value exceeding a certain threshold is detected,
Judge as deterioration or failure. Even if the optical linear repeater determines that the optical linear repeater has deteriorated or failed, the optical regenerative repeater or the multiplexing terminal equipment located downstream does not necessarily detect the deterioration of the transmission line quality. That is, even if the optical linear repeater determines that the optical linear repeater has deteriorated or failed, the system switching does not operate, and the optical linear repeater determined to have deteriorated or failed may be used. This is because the optical regenerative repeater and the multiplexing terminal detect a digital signal code error, while the optical linear repeater cannot recognize the digital signal. Even if the optical linear repeater makes a self-diagnosis of deterioration or failure and notifies the maintenance person with a lamp, etc., it is difficult to determine whether the transmission line including the optical linear repeater is used or not used because of the backup transmission line. Absent. For this reason, even if the optical linear repeater determines that the optical linear repeater has deteriorated or failed, the station in which the optical linear repeater is installed may not be able to perform multiplexing if the maintenance person replaces the package or resets the line control items. It is necessary to confirm the use state of the optical linear repeater to the station where the terminal equipment is installed.

The present invention solves the above-mentioned drawbacks. In the case where a maintenance person replaces a package of an optical repeater or resets a line control item, the use state of a transmission line is set to an installation station of a multiplexing terminal equipment. It is an object of the present invention to provide a digital relay transmission system capable of determining without confirming the transmission.

[0017]

SUMMARY OF THE INVENTION The present invention provides a CCITT
G. FIG. 707, G.C. 708, G.C. 709, a high-speed optical signal transmission line, and an optical repeater interposed in the transmission line, in the digital repeater transmission system, the optical repeater includes a multiple transfer mode frame (STM frame) included in a synchronous transfer mode frame (STM frame). Section overhead (MS-OH)
And a means for monitoring the K2 byte in and the alarm generated by the apparatus itself, and a means for determining the use state of the transmission line based on a predetermined reference based on the monitoring result.

Further, the present invention can include means for monitoring the K1 byte together.

Further, according to the present invention, there may be provided a means for displaying a judgment result of the judging means.

Further, when an optical linear repeater is inserted in the transmission line, the determination result obtained by the determination means obtained by the device on the upstream side of the optical linear repeater is transmitted to the optical linear repeater. A monitoring line different from the above-mentioned transmission line can be provided.

[0021]

The optical regenerative repeater monitors the K2 byte in the multiple section overhead contained in the STM frame and the alarm generated by the optical regenerator in the case of the redundant system having the switchback, or performs the operation of the redundant system without the switchback. ST in case
The K1 byte and K2 byte in the multiple section overhead included in the M frame and the alarm generated by the own device are monitored, and based on the monitoring result, the use state of the transmission path is determined based on a predetermined reference, and the determination result is displayed. Further, in the case of an optical linear repeater, the use state of the transmission line is determined based on a prescribed reference based on the use state of the transmission line notified from the upstream device via the monitoring line and the alarm generated by the own device. Display the judgment result. Thus, when the maintenance person performs the switching of the package of the optical repeater or the resetting of the line control item, it is possible to determine without confirming the use state of the transmission line to the installation station of the multiplex terminal equipment.

[0022]

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a digital relay transmission system according to a first embodiment of the present invention. In FIG. 1, a digital repeater transmission system includes a high-speed optical signal transmission line conforming to CCITT G.707, G.708, and G.709, and an optical regenerator 21 as an optical repeater inserted in the transmission line. And multiplexing terminal devices 10 _{1 and} 10 ₂ provided at both ends of the transmission line.

Here, the feature of the present invention is that the optical regenerator 21 monitors the K2 byte in the multiple section overhead included in the STM frame and the alarm generated by its own device, Means for judging the use state of the transmission line based on a predetermined criterion.

An ACT lamp is provided as a means for displaying the result of the judgment by the judgment means.

The operation of the optical repeater having such a configuration will be described.

FIG. 1 shows a digital relay transmission system having an N: 1 redundant system configuration. FIG. 2 is a diagram showing the transition conditions for turning on and off the ACT lamp of the optical regenerative repeater of the digital repeater transmission system according to the first embodiment of the present invention. FIG. 3 is a transition diagram of turning on and off the ACT lamp of the optical regenerative repeater of the first embodiment of the present invention. Here, FIG.
FIG. 3A shows a case where the transmission line number is “0”, and FIG.
(B) shows a case where the transmission line number is other than “0”. In FIG. 1, when the optical regenerative repeater 21 determines the use state of the transmission path, it can notify a maintenance person or a monitoring system by lamp lighting, voltage change, resistance change, message output, and the like. Here, as a specific means, a case will be described in which an ACT lamp is mounted on the optical regenerator 21 in a system having an N: 1 redundant system with switching back. In FIG. 2, three consecutive receptions of the same content are recognized as transition conditions.... Indicates that the condition is arbitrary. If a plurality of transition conditions are monitored at the same time, transition takes place with the following priority. a>b> c, d TF indicates loss of output, LOS indicates loss of input, and LOF indicates loss of frame synchronization. FIG. 2 shows the transition conditions for turning on and off the ACT lamp in the optical regenerator 21 of the system having the N: 1 redundant system with the switching back. Transition conditions for turning on and off the ACT lamp can be classified into five items a to e. Where K2
The bytes (b1-b4) indicate the numbers of the transmission lines connected to the protection transmission lines.

When power is supplied to the optical regenerator 21 and the system is started up, the optical regenerator 21 is set to what number the transmission line number is from “0” to “15”. I do. “0” is set for the spare transmission line, “1” to “14” is set for the used transmission line, and “15” is set for EXTRA TRAFFIC.

First, to a transmission line of "0" (standby transmission line),
The case where the optical regenerator 21 is connected will be described. The ACT lamp is turned on and off as shown in FIG. 3A based on the transition condition (FIG. 2) determined by the K2 byte of the up and down and the monitoring contents of the alarm. This transition condition is determined by the K2 byte of the up and down and the alarm of the own device. For example, when the optical input loss (LOS) is detected in the own device, the transition condition becomes a.

The optical regenerative repeater 21 connected to the "0" transmission line (standby transmission line), regardless of the use state of the transmission line
The ACT lamp is turned off when the system is started. A, b, c, e while the ACT lamp of the optical regenerator 21 is turned off
Is detected, since the transmission line of “0” is not in use, the ACT lamp is kept turned off.

A is input loss (TF) in the transmission path,
Failures such as loss of output (LOS) and loss of frame synchronization (LOF) occur. When a failure occurs in the transmission line of “0”, the switching to the transmission line of “0” is not performed, so that the transmission line of “0” is unused. For this, A
The CT lamp continues to be turned off.

B is MS-AIS (Alarm Indication Signal)
, Alarm display signal), FERF (Far EndReceive Failure,
This is the case where a far-end reception failure is monitored. When the MS-AIS and FERF are monitored on the transmission line of “0”, the ACT lamp of the optical regenerator 21 connected to the transmission line of “0” because the transmission line of “0” is unused. Keeps off.

The case “c” is a case where “transmission line number 0” is monitored by the K2 byte (b1-b4). This means that the spare transmission line is connected to the transmission line number 0, that is, the spare transmission line is not used, and the transmission line of “0” is unused. For this reason, the ACT lamp continues to be turned off.

E is a condition when the switching sequence is not completed, for example, the contents of the bidirectional K2 bytes (b1-b4) are not equal. Because this state is indeterminate,
The ACT lamp continues to be turned off.

When d is detected while the ACT lamp of the optical regenerator 21 is turned off, the ACT lamp is turned on because the transmission line of "0" is in use. “d” indicates a case where “other than transmission line number 0” is monitored in the K2 byte (b1-b4). This means that the spare transmission line is connected to a line other than the transmission line number 0, that is, the spare transmission line is being used, and the transmission line “0” is in use. For this reason, the ACT lamp is turned on.

If d and e are detected while the ACT lamp of the optical regenerative repeater 21 connected to the transmission line of "0" is lit, the transmission line of "0" is in use, so Continue lighting. “d” indicates a case where “other than transmission line number 0” is monitored in the K2 byte (b1-b4). This means that the standby transmission line is connected to a line other than the transmission line number 0, that is, the standby transmission line is being used, and the transmission line of “0” is in use. For this, AC
The T lamp continues to light.

E is a condition when the switching sequence is not completed, for example, when the contents of the bidirectional K2 bytes (b1-b4) are not equal. Because this state is indeterminate,
The ACT lamp continues to light.

If a, b, and c are detected while the ACT lamp of the optical regenerator 21 connected to the transmission line of "0" is lit, the transmission line of "0" is not used. Turn off the ACT lamp. a shows a case where a failure such as an input disconnection, an output disconnection, and a loss of frame synchronization has occurred in the transmission path “0”. If a failure occurs on the transmission line of 0 ",
Since switching to the transmission path of “0” is not performed, “0”
Are unused. Therefore, the ACT lamp is turned off.

FIG. 4B shows a case where MS-AIS and FERF are monitored. When MS-AIS and FERF are monitored on the transmission line of “0”, the transmission line of “0” is unused,
ACT of the optical regenerator 21 connected to the transmission line of “0”
The lamp goes off.

C is a case where "transmission line number 0" is monitored by the K2 byte (b1-b4). This means that the standby system is connected to the transmission line number, that is, the standby transmission line is not used, and the transmission line of “0” is unused. Therefore, the ACT lamp is turned off.

Next, a case where the optical regenerator 21 is connected to a transmission line other than "0" will be described. On and off of the ACT lamp based on the transition condition (FIG. 2) determined by the up and down K2 bytes and the monitoring contents of the alarm,
The transition is made as shown in FIG. The optical regenerator 21 connected to a transmission line other than “0” applies the AC of the transmission line other than “0” at system start-up regardless of the use state of the transmission line.
Turn on the T lamp. Optical regenerative repeater 2 connected to a certain transmission line other than “0” (“n” in this example)
When d and e are detected while the ACT lamp 1 is turned on,
Since the transmission path "n" is in use, the ACT lamp is kept turned on. d is “n” in K2 bytes (b1-b4).
"Other" is monitored. This means that the standby transmission line is connected to a transmission line other than “n”, that is, the transmission line of “n” is not connected to the standby transmission line, and the transmission line of “n” is in use. Becomes For this,
The ACT lamp continues to light.

E is a condition when the switching sequence is not completed, for example, when the contents of the bidirectional K2 bytes (b1-b4) are not equal. Because this state is indeterminate,
The ACT lamp continues to light.

The ACT of the optical regenerator 21 connected to one transmission line other than "0"("n" in this example)
If a, b, and c are detected while the lamp is on, "n"
The ACT lamp is turned off because the transmission line is not used. a shows a case in which a failure such as an input disconnection, an output disconnection, and a loss of frame synchronization has occurred in the transmission line.
The transmission line of “n” becomes unused, and the ACT lamp is turned off.

B shows the case where MS-AIS and FERF are monitored. When the MS-AIS and FERF are monitored on the transmission line “n”, the transmission line “n” is unused,
ACT of the optical regenerator 21 connected to the transmission line "n"
The lamp goes off.

C is the case where the "transmission line number n" is monitored by the K2 byte (b1-b4). This means that the transmission line "n" is connected to the spare transmission line, that is, "n".
Means that the transmission line of the “n” is switched to the spare transmission line, and the transmission line of “n” is unused. For this, A
The CT lamp goes out.

The ACT of the optical regenerative repeater 21 connected to one transmission line other than “0” (“n” in this example)
If a, b, c, e are detected while the lamp is off,
Since the transmission line “n” is not used, the ACT lamp continues to be turned off. a shows a case where a failure such as an input disconnection, an output disconnection, a loss of frame synchronization, or the like has occurred in the transmission path. The transmission path of “n” becomes unused, and the ACT lamp continues to be turned off.

FIG. 6B shows a case where MS-AIS and FERF are monitored. When the MS-AIS and FERF are monitored on the transmission line “n”, the transmission line “n” is unused,
ACT of the optical regenerator 21 connected to the transmission line "n"
The lamp remains off.

C is the case where the "transmission line number n" is monitored by the K2 byte (b1-b4). This means that the transmission line "n" is connected to the spare transmission line, that is, "n".
Means that the transmission line of the “n” is switched to the spare transmission line, and the transmission line of “n” is unused. For this, A
The CT lamp continues to be turned off.

E is a condition when the switching sequence is not completed, for example, when the contents of the bidirectional K2 bytes (b1-b4) are not equal. Because this state is indeterminate,
The ACT lamp continues to light.

The ACT of the optical regenerator 21 connected to one transmission line other than “0” (“n” in this example)
If d is detected while the lamp is off, the ACT lamp continues to be lit because the transmission line "n" is in use. "d" indicates a case where "other than" n "" is monitored in the K2 byte (b1-b4). This means that the spare transmission line is connected to a line other than the “n” transmission line, that is, the “n” transmission line is not connected to the spare transmission line,
The transmission path “n” is in use. For this reason, the ACT lamp is turned on.

FIG. 4 is a block diagram showing a digital relay transmission system according to a second embodiment of the present invention. FIG. 5 is a diagram showing transition conditions for turning on and off the ACT lamp of the optical regenerative repeater of the digital relay transmission system according to the second embodiment of the present invention. FIG. 6 is a transition diagram of turning on and off the ACT lamp when the transmission line number assigned to the optical regenerator of the second embodiment of the present invention is "1". FIG. 7 is a transition diagram of turning on and off the ACT lamp when the transmission line number assigned to the optical regenerator of the digital relay transmission system according to the second embodiment of the present invention is "2".

The second embodiment is different from the first embodiment in that an ACT lamp is mounted on an optical regenerative repeater in a system having a 1: 1 redundant system without switching back. In FIG. 5, forced switching and the like include forced switching, transmission line failure, quality degradation,
Indicates either a recovery standby or a switching response. Recognition of three consecutive receptions of the same content as a transition condition... Indicates that the condition is arbitrary. A>b> c, d, e, f TF indicates output disconnection, LOS indicates input disconnection, and LOF indicates loss of frame synchronization.

FIG. 5 shows the ACT lamp ON / OFF transition conditions in the optical regenerator 22 of a system having a 1: 1 redundant system without switching back. The on / off transition conditions of the ACT lamp can be classified into seven items a to g. Here, the K2 byte (b1-b4) indicates the transmission line number of the transmission line called "working". This does not change until the cause of the switching occurs, the switching is performed according to the cause, and the “switching operation” until the cause of the switching is recovered by some measure ends. In other words, the term “working” used herein is not a word indicating the use or non-use of a transmission line, but a word indicating a transmission line that provides a service when a failure has been recovered and is normal.

When power is supplied to the optical regenerator 22 and the system is started up, the optical regenerator 22 is set to use the transmission path number “1” or “2”. Do.

First, the optical regenerator 2 is sent to the transmission line "1".
2 will be described. Up and down K1, K2
The turning on and off of the ACT lamp transitions as shown in FIG. 6 based on the transition condition (FIG. 5) determined by the byte and the monitoring contents of the alarm. The optical regenerative repeater 22 is set to "1" at system startup regardless of the use state of the transmission line.
The ACT lamp of the transmission line is turned on. When c, d, and g are detected while the ACT lamp is turned on, it is determined that the transmission line of “1” is in use, and the ACT lamp is kept turned on. c is a case where the transmission line of “1” is the working transmission line, both directions are normal, and there is no switching request.
At this time, the optical regenerator 2 connected to the transmission line “1”
2 keeps lighting the ACT lamp.

D indicates that when the transmission line of “2” is currently used, some sort of failure occurs, the switching is performed forcibly in both the up and down directions, and the K1 of the content of the transmission line failure or the like in the optical regenerative repeater 22. When bytes are monitored. At this time, the transmission path in use is the transmission path of “1”. Therefore, the optical regenerator 22 connected to the transmission line of “1” turns on the ACT lamp.

G is a condition when the switching sequence is not established, for example, when the K1 and K2 bytes of contents such as a unidirectional switching request and undefined bit assignment are monitored. Since this state is an uncertain state, lighting of the ACT lamp is continued.

When the optical regenerator 22 connected to the transmission line "1" detects a, b, e, and f while the ACT lamp is turned on, the transmission line "1" is unused. So ACT
The lamp goes off. a is the input disconnection in the transmission path,
This is a case where a failure such as output disconnection or loss of frame synchronization has occurred. When a failure occurs in the transmission line of “1”, switching is performed, so that the transmission line of “1” is unused.
For this purpose, the ACT lamp is turned off.

B shows a case where MS-AIS and FERF are monitored. When MS-AIS and FERF are monitored on the transmission line of “1”, since the transmission line of “1” is not used,
ACT of the optical regenerator 22 connected to the transmission line of “1”
The lamp goes off.

In the case e, when the transmission path of "2" is in use, both the up and down directions are normal and there is no switching request. At this time, the transmission path of “2” is in use and “1”
The ACT lamp of the optical regenerative repeater 22 connected to the transmission line is turned off.

In the case f, when the transmission line of "1" is currently used, some trouble occurs, the switching is performed forcibly in both the up and down directions, and the K1 byte containing the content of the transmission line failure and the like is stored in the optical regenerator. This is the case where monitoring was performed at 22.
At this time, the transmission path in use is the transmission path of “2”. Therefore, the optical regenerator 2 connected to the transmission line of "1"
2 turns off the ACT lamp.

When a, b, e, f, and g are detected while the ACT lamp of the optical regenerator 22 connected to the transmission line "1" is turned off, the transmission line "1" is not used. So that
The ACT lamp turns off. The condition (a) is when a failure such as an input disconnection, an output disconnection, and a loss of frame synchronization occurs in the transmission path. If a failure occurs in the transmission line of “1”, the transmission line of “1” is not in use, and
ACT of the optical regenerator 22 connected to the transmission line of “1”
The lamp remains off.

The condition of b is that MS-AIS,
This is the case when FERF is monitored. When MS-AIS and FERF are monitored on the transmission line “1”, the ACT of the optical regenerator 22 connected to the transmission line “1” is activated because the transmission line “1” is unused. The lamp remains off.

In the case e, when the transmission path “2” is in use, the transmission is normal in both the up and down directions, and there is no switching request. At this time, the transmission path of “2” is in use and “1”
The ACT lamp of the optical regenerative repeater connected to the transmission line of (1) continues to be turned off.

The case f is a case where some failure exists in the currently used transmission line "1", and the K1 byte of contents such as forced switching and transmission line failure in both the upstream and downstream directions is monitored. At this time, the transmission path in use is the spare “2” transmission path. Therefore, the ACT lamp of the optical regenerative repeater 22 connected to the transmission line of “1” continues to be turned off.

G is a condition when the switching sequence is not established, such as when a one-way switching request or an undefined bit assignment is monitored. Since this state is an indeterminate state, the current ACT lamp continues to be turned off.

The optical regenerator 2 connected to the transmission line "1"
When c and d are detected while the ACT lamp of No. 2 is turned off,
Since the transmission path of “1” is in use, the ACT lamp is turned on. c is a case where the transmission path of “1” is active and both the up and down directions are normal and there is no switching request. At this time, the transmission path of “1” is in use and “1”
The ACT lamp of the optical regenerator 22 connected to the transmission line is turned on.

The case d shows the case where some failure exists in the currently used transmission line "2" and the contents of the forced switching in both the up and down directions and the failure of the transmission line are monitored by the K1 byte. At this time, the transmission line in use is a spare “1” transmission line. Therefore, the ACT lamp of the optical regenerative repeater 22 connected to the transmission line of “1” is turned on.

Next, the case of connecting to the transmission line "2" will be described. The ACT lamp is turned on and off based on the transition conditions (FIG. 5) determined by the up-and-down K1 and K2 bytes and the contents of the alarm monitor as shown in FIG.
Transition as follows. The optical regenerator 22 operates at the time of system start-up regardless of the use state of the transmission line of “2”.
Turn off the lamp. Hereinafter, the concept of the transition of the ACT lamp on / off is the same as that of the previous example, and thus the description is omitted.

FIG. 8 is a block diagram showing a digital relay transmission system according to a third embodiment of the present invention. FIG. 9 is a diagram showing transition conditions for turning on and off the ACT lamp of the optical linear repeater of the digital repeater transmission system according to the third embodiment of the present invention. FIG.
FIG. 9 is a transition diagram of turning on and off an ACT lamp of the optical linear repeater of the digital repeater transmission system according to the third embodiment of the present invention.
In FIG. 9, three consecutive receptions of the same content are recognized as transition conditions.... Indicates that they are optional. If a plurality of transition conditions are monitored simultaneously, transition takes place with the following priority. a> b, c> d TF indicates output disconnection and LOS indicates input disconnection.

When the optical linear repeater 24 determines the use state of the transmission line, it can notify the maintenance person or the monitoring system by lighting the lamp, changing the voltage, changing the resistance, issuing a message, or the like.

Since the optical linear repeater 24 amplifies the optical signal as light, it cannot read the information in the section overhead in which the use state is written. Therefore,
It is necessary to be notified of the usage status. here,
A monitoring line dedicated to the optical linear repeater different from the main signal (hereinafter referred to as SV
Called line. ), A method of having the multiplexing terminal device and the optical regenerative repeater 23 notify the use state will be described.
FIG. 8 shows an example of a digital repeater transmission system in which an optical linear repeater 24 is connected between optical regenerative repeaters 23. In this example,
An SV line is installed between the optical regenerative repeater 23 and the optical linear repeater 24. This SV line is installed in one pair (up, down) for one relay section. On the SV line, the use state determined in the upstream optical regenerator 23 (the optical regenerator described in the first and second embodiments) is notified to the optical linear repeater 24. Specifically, the use state is represented by signal bits or bytes of the SV line, and the use state is monitored by the optical linear repeater 24.

As a means for notifying a maintenance person or a monitoring system, the optical linear repeater 2 in a system having a 1: 1 redundant system
4 shows a case where an ACT lamp is mounted. FIG. 9 shows the transition conditions for turning on and off the ACT lamp in the optical linear repeater 24 of the system having the 1: 1 redundant system.
Transition conditions for turning on and off the ACT lamp can be classified into four items a to d. For example, when one of the up and down is the optical input loss (LOS), the value is a. On and off of the ACT lamp are changed as shown in FIG. 10 based on the transition condition of FIG. The optical linear repeater 24 turns off the ACT lamp when the system is started, regardless of the use state of the transmission line.

A case where a certain transition condition is monitored while the ACT lamp is turned off will be described below. a shows a case where an alarm such as an output disconnection or an input disconnection occurs while the ACT lamp of the optical linear repeater 24 is turned off. At this time, the transmission line is unused, and the AC of the optical linear repeater 24 connected to the transmission line is not used.
The T lamp continues to be turned off.

The case b is the case where the use state from the upstream is monitored as being used while the ACT lamp of the optical linear repeater 24 is turned off. At this time, the transmission line is in use, and the ACT lamp of the optical linear repeater 24 connected to the transmission line is turned on.

The case c is a case where the state of use from the upstream is monitored as unused while the ACT lamp of the optical linear repeater 24 is turned off. At this time, the transmission line is not used,
The ACT lamp of the optical linear repeater 24 connected to the transmission line continues to be turned off.

The case d is a case where information other than the transition conditions a, b and c is monitored while the ACT lamp of the optical linear repeater is turned off. At this time, since the use state of the transmission path is uncertain, the state of the ACT lamp is continued and the ACT lamp is turned off.

A case where a certain transition condition is monitored while the ACT lamp is turned on will be described below. a shows a case where an alarm such as an input disconnection or an output disconnection occurs while the ACT lamp of the optical linear repeater 24 is on. At this time, the transmission line is unused, and the optical linear repeater 2 connected to the transmission line is not used.
The ACT lamp 4 is turned off.

FIG. 7B shows a case where the state of use from the upstream is monitored as being used while the ACT lamp of the optical linear repeater 24 is on. At this time, the transmission line is not used,
The ACT lamp of the optical linear repeater 24 connected to the transmission line keeps lighting.

The case c is a case where the state of use from the upstream is monitored as being unused while the ACT lamp of the optical linear repeater 24 is on. At this time, the transmission line is unused, and the ACT of the optical linear repeater 24 connected to the transmission line is not used.
Turn off the lamp.

The case d is a case where information other than the transition conditions a, b, and c is monitored while the ACT lamp of the optical linear repeater 24 is turned on. At this time, since the use state of the transmission path is uncertain, the ACT lamp state is continued and is turned on.

As described above, the case where the optical linear repeater is provided between the optical regenerative repeaters has been described. However, the optical linear repeater is provided between the multiplexing terminal equipments or between the optical regenerative repeater and the multiplexing terminal. The use state can be determined in the same manner even when provided between the apparatus and the apparatus.

[0083]

As described above, according to the present invention, in the optical regenerative repeater, the K2 byte and the K1 byte are used in the case of the redundant system with the switchback and the alarm, and the K1 byte in the case of the redundant system without the switchback. The use state of the transmission path can be determined by the K2 byte and the alarm. In addition, the optical linear repeater can determine the use state of the transmission line by notifying from the upstream device via the SV line. Therefore, it is possible to mount the ACT lamp on the optical regenerative repeater and the optical linear repeater, it is possible to accurately notify the maintenance person of the use state of the main signal package, and to maintain the optical regenerative repeater and the optical linear repeater. There is an excellent effect that can be executed reliably.

[Brief description of the drawings]

FIG. 1 is a block diagram of a digital relay transmission system according to a first embodiment of the present invention.

FIG. 2 is a diagram showing transition conditions for turning on and off an ACT lamp of the optical regenerative repeater of the digital relay transmission system according to the first embodiment of the present invention.

FIG. 3 is a transition diagram of turning on and off an ACT lamp of the optical regenerative repeater of the digital relay transmission system according to the first embodiment of the present invention.

FIG. 4 is a block diagram showing a digital relay transmission system according to a second embodiment of the present invention.

FIG. 5 is a diagram showing transition conditions for turning on and off an ACT lamp of an optical regenerative repeater using a digital relay transmission system according to a second embodiment of the present invention.

FIG. 6 shows a second embodiment of the present invention in which the transmission line number assigned to the optical regenerator in the digital repeater transmission system is “1”;
FIG. 4 is a transition diagram of turning on and off a CT lamp.

FIG. 7 is a diagram showing A in the case where the transmission line number assigned to the optical regenerator of the digital relay transmission system according to the second embodiment of the present invention is "2";
FIG. 4 is a transition diagram of turning on and off a CT lamp.

FIG. 8 is a block diagram of a digital relay transmission system according to a third embodiment of the present invention.

FIG. 9 is a diagram showing transition conditions for turning on and off an ACT lamp of an optical linear repeater of a digital repeater transmission system according to a third embodiment of the present invention.

FIG. 10 is a transition diagram of turning on and off the ACT lamp of the optical linear repeater ACT of the digital repeater transmission system according to the third embodiment of the present invention.

FIG. 11 is a block diagram of a digital relay transmission system.

FIG. 12 is a configuration diagram of an STM frame of the digital relay transmission system.

FIG. 13 is a switching sequence diagram showing a switching operation of the digital relay transmission system.

FIG. 14 is a diagram showing a definition of a K1 byte of a multiple section overhead of the digital relay transmission system.

FIG. 15 is a diagram showing a definition of a K2 byte of a multiple section overhead of the digital relay transmission system.

FIG. 16 is a block diagram of a conventional digital relay transmission system.

[Explanation of symbols]

10 ₁ , 10 ₂ , multiplexing terminal equipment 20 optical repeaters 21, 22, 23, 24 optical regenerative repeaters 24 optical linear repeaters

Continuation of the front page (56) References JP-A-3-52440 (JP, A) JP-A-3-112240 (JP, A) JP-A-5-292083 (JP, A) JP-A-6-164558 (JP) , A) JP-A-5-327767 (JP, A) Proceedings of the IEICE Communication Society Conference, B-758 (1995-8-15), p425 NTTR & D, Vol. 44, no. 3 (1995-3-10), p. 25-37 (58) Field surveyed (Int. Cl. ⁷ , DB name) H04J 3/00-3/26

Claims (4)

(57) [Claims] A CCITT G. 707, G.C. 708,
G. FIG. 709, a high-speed optical signal transmission line, and an optical repeater interposed in the transmission line, wherein the optical repeater includes a multiple transmission mode frame (STM frame) included in a synchronous transfer mode frame (STM frame). The system includes means for monitoring the K2 byte in the section overhead (MS-OH) and an alarm generated by the apparatus itself, and means for judging the use state of the transmission line based on a predetermined reference based on the monitoring result. Digital relay transmission system. 2. The digital relay transmission system according to claim 1, further comprising means for monitoring the K1 byte. 3. The digital repeater transmission system according to claim 1, further comprising means for displaying a determination result of said determination means. 4. When an optical linear repeater is inserted in the transmission line, a determination result of the determination means obtained by a device on the upstream side of the optical linear repeater is transmitted to the optical linear repeater. 3. The digital repeater transmission system according to claim 1, further comprising a monitoring line different from said transmission line.