JP3014602B2 - Transmission line monitoring method for optical transmission system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission system for transmitting an optical signal between a master station and a plurality of slave stations connected to, for example, a plurality of optical transmission lines formed in a loop. The present invention relates to a transmission line monitoring method for an optical transmission system that monitors a transmission line.

[0002]

2. Description of the Related Art Conventionally, as an optical transmission system of this type, there is an optical multi-drop system for performing bidirectional transmission of an optical signal using an optical transmission line configured in a double loop, for example.
In the optical multi-drop system, a master station and a plurality of slave stations are connected to an optical transmission line. Here, when performing optical transmission, the master station first transmits a burst signal composed of a preamble section, an information body section, and a postamble section as shown in FIG. While transmitting, the own station also receives the burst signal and monitors the optical transmission path. When the state of the optical transmission line is abnormal, a burst signal is transmitted from another optical transmission line and the burst signal is received to determine the state of the optical transmission line.

[0003] The preamble portion of the burst signal is used for stabilizing the signal generation time by the station to communicate with the signal generation station and the burst signal receiving station. This is the part that secures enough time. As shown in FIG. 5, the information main unit includes a synchronization word including a bit synchronization word for performing bit synchronization and a frame synchronization word for performing frame synchronization, and a control word in which control information is stored. It consists of a composed frame (two words). For example, as shown in FIG. 6, 20 bits of information of repetition of "1" and "0" are stored in the bit synchronization word.
For example, as shown in FIG. 7, 20 bits of information in which the first and last bits are "1" and all the bits are "0" are stored in the frame synchronization word.

[0004] The postamble section is the time until the burst signal disappears. In such a system, for example, in a facility such as a substation, when a control center controls a slave station arranged along a distribution line feeder, an optical coupling device is provided at a substation which is an entrance of the feeder. Some relay the signals from the control center.
In this system, since the slave-station-side control line is laid and wired along the distribution line, a relatively abnormal line occurs due to a failure due to a failure accident or the like. For this reason, for example, in an optical coupling device, there has been a method in which a burst signal having information to be transmitted is shifted in time in a different direction to a plurality of lines regardless of the presence or absence of a line abnormality, and the same information is transmitted.

[0005]

However, the above-mentioned monitoring method has a problem that the time required for transmitting information is twice or more, and the line use efficiency is low. In addition, there is a method of transmitting information for monitoring a transmission path separately from information to be transmitted (for example, by using a different frame). However, there was a problem that the frequency of the operation was reduced.

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above problems, and has as its object to provide a transmission path monitoring method for an optical transmission system that can detect an abnormality in an optical transmission path in a short time.

[0007]

According to the present invention, an optical signal having an information body is transmitted between a master station connected to a plurality of optical transmission lines and a plurality of slave stations. in the master station an optical transmission system for receiving the optical signal by the own station transmits, the master station of the optical transmission path first
A first transmission step of transmitting, to one optical transmission line, the optical signal obtained by adding predetermined information to a head portion of the information main body;
A first detecting step of receiving the optical signal and detecting a state of the first optical transmission line based on predetermined information of the head portion; and detecting an abnormal state in the first optical transmission line. A second transmission step of stopping transmission of an optical signal in the first transmission step and transmitting the optical signal to a second optical transmission path of the optical transmission paths; And a second detection step of detecting a state of the second optical transmission line based on predetermined information of the head portion, and detecting an abnormal state of the second optical transmission line, While continuing the transmission of the optical signal in the second transmission step, the first
And a third transmission step of transmitting the optical signal to the optical transmission line.

[0008] A transmission line monitoring method according to claim 3, in the first optical transmission line, to transmit optical signals from a particular direction, the second optical transmission path, an optical signal from the direction opposite to the specific direction Send. A transmission line monitoring method according to claim 4, provided a predetermined coding rule to information added to f Tsu <br/> head portion of the information main body section, if the information is in accordance with the coding rule, the optical transmission path state Is detected as normal.

[0009]

[Operation] The master station transmits the information body of the optical signal to be transmitted to the slave station .
Since predetermined information is added to the head portion and only the received predetermined information is monitored to detect an abnormality in the optical transmission line,
The above detection can be performed very quickly. According to the transmission path monitoring method of the third aspect, when an abnormality is detected in both of the optical transmission paths, the optical transmission can be performed to the required maximum of the slave stations.

In the transmission line monitoring method according to the fourth aspect, the abnormality is detected in the optical transmission line in accordance with the coding rule of the information added to the head portion of the information main body, so that the above detection is facilitated.

[0011]

1 to 3 show a transmission line monitoring method according to the present invention.
This will be described with reference to the drawings. FIG. 1 shows a transmission according to the invention.
FIG. 2 is a block diagram illustrating a configuration of an optical transmission system using a route monitoring method. In the figure, the optical transmission system is a multi-drop type double loop and has two optical transmission lines 1.
A master station 20 and a plurality of slave stations 30 are connected to 0 and 11.

The master station 20 has two optical transmitters T each.
1, T2, optical receivers R1, R2, and a control unit 21. The one set of optical transmitter T1 and the optical receiver R1 are connected to the end of the optical transmission line 10, and the other set of optical transmitter T1
2 and the optical receiver R2 are connected to the end of the optical transmission line 11. The optical transmitters T1, T2 and the optical receivers R1, R2 are:
For example, the burst signal (optical signal) shown in FIG. 4 composed of a CMI (Coded Mark Inversion) code is transmitted and received via the optical transmission lines 10 and 11 at a transmission speed of 1.544 Mbps.

The control section 21 stores information of a predetermined coding rule necessary for recognizing whether or not the state of the optical transmission line is abnormal in the information body of the optical signal composed of the burst signal shown in FIG. The signal is additionally output to the optical transmitter. As shown in FIGS. 5 to 7, the information body is composed of words. The bit synchronization word is used by each slave station 30 to synchronize the bit of the burst signal. In the example, it is assumed that the information of the predetermined coding rule is added to the head portion of the bit synchronization word. The information of the predetermined code rule uses, for example, about 2 bits of the head portion. Further, for the information, for example, a CMI code is used. This is because there is no restriction on the performance and price of the electric-to-optical converter (not shown) of the transceiver,
This is because the circuit scale required for encoding and decoding is small, and the frame synchronization scale for determining the read position of the multiplex signal can be easily configured by CRV (Code Rule Volation).

Further, the control unit 21 controls the switching between the optical transmitter and the optical receiver for transmitting and receiving the optical signal, transmits the optical signal from the controlled optical transmitter T1 or T2, and makes a round of the optical transmission line. The optical signal is received and captured by the optical receiver R1 or R2 paired with the optical transmitter. Then, the state of the optical transmission line is determined by detecting whether or not the predetermined information in the bit synchronization word head portion in the information main body does not violate the CMI coding rule. In the master station 20 of this embodiment, an optical signal is transmitted to one optical transmission line 10 in a specific direction (clockwise direction in the figure), and an optical signal is transmitted to the other optical transmission line 11. The direction opposite to the direction (in the figure,
(From the counterclockwise direction).
When an abnormality is detected due to a failure such as a disconnection of 0 and 11, an optical signal is transmitted to both optical transmission lines 10 and 11,
Optical transmission to the required maximum of slave stations.

Each slave station 30 has a set of optical transmitters T
And the optical receiver R. The optical transmitter T and the optical receiver R are connected via the closure 31 to both optical transmission lines 10 and 11.
Connected to each other. The optical branching device used in the closure 31 is preferably one that can perform bidirectional branching, for example, using an X coupler and a Y branch. Thus, the optical transmitter T and the optical receiver R of each slave station 30 are connected to both optical transmission lines 1
0 and 11 respectively, and any of the optical transmission lines 1
Optical signals can be transmitted and received to and from 0 and 11 as well. Each slave station 30 transmits and receives an optical signal in response to a call from the master station 20.

The internal signal processing performed by the slave station 30 converts the CMI code on the optical transmission lines 10 and 11 into a code to convert the CMI code into a signal such as an NRZ signal having a transmission rate of 200 bps. (Non Return to Zer
o) Detected as a sign. That is, since the transmission speed of the optical signal in the slave station 30 is 200 bps, the speed per bit is (1/200) = 5 ms.
On the other hand, in the CMI code on the optical transmission line, the transmission speed is 1.5
So 44 Mbps, 1-bit information in the CMI code ^{(1.544 × 10 6/200)} = 7720 pieces and become,
Since the above CRV detection requires two codes, 7720 /
2 = 3860. Therefore, in the CMI code, NR
It is sufficient to use about 1/3860 for one bit of the Z code.

That is, pulse jitter (temporal fluctuation)
Occurs on the order of several percent, so
The predetermined information added to the information body of the optical signal is:
This is because the start of the bit synchronization word can be regarded as a noise fluctuation of 0.1% or less, and is practically included in the fluctuation range of the jitter and cannot be distinguished from the jitter. In addition, parent station 2
The predetermined information necessary for 0 to recognize the state of the optical transmission line is:
The bit synchronization word is about 2 to 3 bits, and the bit of the bit synchronization word is usually about 20 bits. It doesn't matter.

Next, the operation of the optical transmission system shown in FIG. 1 will be described. First, when optical transmission is performed, the control unit 21 of the master station 20 adds predetermined information composed of a CMI code to the bit synchronization word head portion of the information body of the burst signal shown in FIG. Then, the optical transmitter T1 calls the slave station 30 via the one optical transmission line 10 and the closure 31, transmits the burst signal to the slave station 30 clockwise from the one optical transmission line 10, and The optical receiver R1 receives the burst signal that has been cycled by the station.

Next, the control unit 21 fetches the received burst signal, detects whether predetermined information in the bit synchronization word head portion does not violate the CMI coding rule, and determines the state of the optical transmission line. . Here, the control unit 21
When the burst signal is received and the predetermined information in the bit synchronization word head does not violate the CMI coding rule, the state of the optical transmission line 10 is determined to be normal, and the signal transmission is continued as it is. . Thereby, each slave station 30
Can normally receive an optical signal with synchronization.

If the burst signal is not received after a certain period of time, or if the predetermined information violates the CMI coding rule even if the burst signal is received, the control unit 21 controls the optical transmission path. In the state 10, it is determined that an abnormality has occurred due to a disconnection or the like, and the transmission of the burst signal to the optical transmission line 10 is immediately stopped. Then, switching control between the optical transmitter and the optical receiver is performed, and the burst signal is transmitted counterclockwise from the optical transmitter T2 via the other optical transmission line 11 to the slave station 30.
, And the optical receiver R2 receives the above-mentioned burst signal which has also made a round in its own station. The predetermined time for receiving the burst signal is set in consideration of the signal speed of the burst signal, the line length of the optical transmission line, and the information processing time.

Next, the control unit 21 fetches the received burst signal in the same manner as described above, detects whether the predetermined information in the bit synchronization word head portion does not violate the CMI coding rule, and checks the state of the optical transmission line 11. Judge. Here, the control unit 21 determines that the state of the optical transmission line 11 is normal when the burst signal is received and the predetermined information of the bit synchronization word head portion does not violate the CMI coding rule.
Signal transmission is continued as it is. Thereby, each slave station 30 can normally receive the optical signal.

Further, the control unit 21 determines whether or not the burst signal is received, or if the burst signal is received.
When the predetermined information is defeated CMI coding rule, the state of the optical transmission line 11 is judged that an abnormality has occurred by disconnection or the like, transmission of the burst signal, while continuing, semi 2
In the double communication system, one optical transmission line 1 is transmitted from the optical transmitter T1.
The burst signal is transmitted to the slave station 30 clockwise through “0”. Thus, even if the optical transmission lines 10 and 11 are disconnected at the position indicated by the mark x shown in FIG. 1, for example, the burst signal is transmitted to the two optical transmission lines 10 and 11 from opposite directions so that the necessary Can be transmitted to child stations.

As described above, in this embodiment, the information of the predetermined coding rule is added to the bit synchronization word head portion of the optical signal to be transmitted to the slave station, and only the above-mentioned predetermined information received in one cycle is monitored, and the optical signal is monitored. Since the abnormality of the transmission line is determined, the failure of the optical transmission line can be detected very quickly. Therefore, when the optical transmission system according to the present invention is applied to equipment such as a substation,
The response to the system main body is quickened, and the return time to the center can be prevented from being expired.

Further, in this embodiment, since an optical signal in which predetermined information is added to a bit synchronization word head portion using an optical double loop line is transmitted in opposite directions from both optical transmission lines, even when a disconnection occurs. The optical signal can be transmitted to the required maximum number of slave stations, and the reliability of optical transmission can be improved. In the present embodiment, the same predetermined information is added to the bit synchronization word head portion. However, the present invention is not limited to this. For example, it is possible to transmit the inverted information of the predetermined information to one optical transmission line. It is also possible to set.

In this embodiment, the predetermined information is added to the bit synchronization word. However, the present invention is not limited to this. For example, the predetermined information (monitoring signal) is added to the head portion of the frame synchronization word. It is also possible to set so as to monitor the predetermined information transmitted to the optical transmission line and received in one round to determine the abnormality of the optical transmission line. However, in this case, as shown below, it is possible to use a monitoring signal that is sufficiently shorter than the synchronization rising time.

That is, as described above, since the frame transmission rate is 200 bps, the rising pulse width τ per bit is (1/200) as shown in FIG.
= 5 ms, that is, the duration is 5 ms / bit. Considering this in a specific example of a capture circuit provided in an optical receiver for receiving a burst signal as shown in FIG. Startup pulse width τ per bit
Should be sufficient as long as the rising time is sufficiently satisfied (see FIG. 2). For example, if T is 1/10 of τ, then T ≒ τ / 10 = 0.5 ms. In this case, assuming that the resistance R is 1 kΩ, for example, the capacitor C is C = T / R = 0.5 μF = 500 nF.

On the other hand, the monitoring signal must be one that does not hinder the above-mentioned startup sufficiently. That is,
Assuming that the rising pulse width of the monitor signal is τ1, τ1 ≒ T / 10 = 0.05 ms = about 50 ns. Therefore, in this embodiment, when an optical pulse of several tens ns is added to the head portion of the synchronous frame,
Since the monitor signal is established when 4 to 5 pulses of τ1 are satisfied, the monitor signal can be sufficiently added within the rise time of the main bit, and the master station separates the monitor signal from the frame synchronization word when receiving the frame. As a result, it is possible to capture with high impedance.

[0028]

As described above, according to the present invention, an optical signal having an information main body is transmitted between a master station connected to a plurality of optical transmission lines and a plurality of slave stations. In the optical transmission system for receiving the optical signal transmitted by the own station, the master station is configured to add the predetermined information to a first optical transmission line of the optical transmission line and to add a predetermined information to a head portion of the information main body. A first transmitting step of transmitting the optical signal;
A first detecting step of detecting a state of the first optical transmission line based on predetermined information of the head portion, and, if an abnormal state is detected in the first optical transmission line, the first transmission Stopping the transmission of the optical signal by the step,
A second transmitting step of transmitting the optical signal to a second optical transmission line, and receiving the optical signal and detecting a state of the second optical transmission line based on predetermined information of the head portion . A second detection step, and when detecting an abnormal state of the second optical transmission line, while continuing the transmission of the optical signal in the second transmission step, the first optical transmission line Since the method includes the third transmission step of transmitting the optical signal, abnormality detection of the optical transmission line can be performed in a short time.

In the transmission line monitoring method according to the third aspect, the optical signals are transmitted to the first optical transmission line and the second optical transmission line from opposite directions, respectively. Can be transmitted to slave stations. In the transmission path monitoring method according to the fourth aspect, the information added to the head portion of the information main body section has a predetermined encoding rule. Therefore, if the information complies with this encoding rule, the state of the optical transmission path is determined to be normal. I can judge.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an optical transmission system using a transmission state monitoring method according to the present invention.

FIG. 2 is a diagram illustrating a relationship between a pulse width of a bit in a frame and a rise time.

FIG. 3 is a diagram illustrating an example of a configuration of a capturing circuit in the optical receiver.

FIG. 4 is a diagram illustrating an example of a configuration of a burst signal used in an optical transmission system.

FIG. 5 is a diagram illustrating an example of a configuration of an information main body of a burst signal illustrated in FIG. 4;

FIG. 6 is a diagram illustrating an example of a configuration of a bit synchronization word of the information main unit illustrated in FIG. 5;

FIG. 7 is a diagram illustrating an example of a configuration of a frame synchronization word of the information main unit illustrated in FIG. 5;

[Explanation of symbols]

 10, 11 optical transmission line 20 master station 21 control unit 30 slave station 31 closure T, T1, T2 optical transmitter R, R1, R2 optical receiver

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-2-290348 (JP, A) JP-A-2-270430 (JP, A) JP-A-62-47246 (JP, A) JP-A-6-47246 14040 (JP, A) JP-A-8-149149 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H04L 12/437

Claims (4)

(57) [Claims] An optical signal having an information body is transmitted between a master station connected to a plurality of optical transmission lines and a plurality of slave stations,
In the optical transmission system in which the master station receives an optical signal transmitted by the master station, the master station adds predetermined information to a first optical transmission line of the optical transmission lines to a head portion of the information main body. A first transmitting step of transmitting the optical signal, a first detecting step of receiving the optical signal and detecting a state of the first optical transmission path based on predetermined information of the head portion ; When an abnormal state is detected in the first optical transmission line, the transmission of the optical signal in the first transmission step is stopped, and the optical signal is transmitted to the second optical transmission line among the optical transmission lines. A second transmitting step of transmitting a signal; a second detecting step of receiving the optical signal and detecting a state of the second optical transmission path based on predetermined information of the head portion; When an abnormal state of the optical transmission line is detected, the optical signal of the second transmission While continuing the signal, the a first optical transmission path, the transmission path monitoring method for an optical transmission system characterized by comprising a third transmission step of transmitting the optical signal. 2. An optical signal having an information main body is transmitted between a master station connected to a plurality of optical transmission lines and a plurality of slave stations,
In the optical transmission system in which the master station receives an optical signal transmitted by the master station, the master station adds predetermined information to a first optical transmission line of the optical transmission lines to a head portion of the information main body. A first transmitting step of transmitting the optical signal, a first detecting step of receiving the optical signal and detecting a state of the first optical transmission path based on predetermined information of the head portion ; When an abnormal state is detected in the first optical transmission line, the transmission of the optical signal in the first transmission step is stopped, and the predetermined optical transmission line is transmitted to the second optical transmission line. a second transmission step of transmitting an optical signal inversion information is added to the head portion of the information main body of information, based on the inversion information of the head portion to receive the optical signal, the second optical transmission line A second detecting step of detecting a state of the second optical transmission line, and detecting an abnormal state of the second optical transmission line. When, along with continued transmission of the optical signal by the second transmission step, said the first optical transmission line, characterized by comprising a third transmission step of transmitting said optical signal A transmission path monitoring method for an optical transmission system. 3. In the first transmitting step, the optical signal is transmitted from a specific direction. In the second transmitting step, the optical signal is transmitted from a direction opposite to the specific direction. The transmission path monitoring method for an optical transmission system according to claim 1 , wherein, in the transmitting step, the optical signal is transmitted to the first optical transmission path from a specific direction. 4. The information added to a head portion of the information main body is information based on a predetermined coding rule, and
And in the second detecting step, the optical signal is received, and when the information complies with the predetermined code rule, the state of the optical transmission path is detected as normal. 3. The transmission path monitoring method for an optical transmission system according to item 2.