KR100298321B1 - Controlling method for outputting optic signal in transmission system - Google Patents

Abstract

end. The technical field to which the invention described in the claims belongs

The present invention relates to a method of controlling the output of an optical signal in an optical transmission system.

I. The technical problem to be solved by the invention

The present invention provides a method of controlling the output of an optical signal of an adjacent station in an optical transmission system without an optical amplifier that blocks an optical signal when the optical path is cut in the optical transmission network.

All. Summary of Solution of the Invention

The present invention is a method of controlling the optical signal output of the power transmission system when the line is cut in the optical transmission system not provided with an optical amplifier, the main control unit to check whether the cutting alarm signal according to the cutting of the line from the optical receiver; When the alarm signal according to the cutting line is received as a result of the inspection, generating, by the main control unit, a line cutting message to be transmitted to the power station, and outputting the cut line message to the data transmission unit; Inserting and outputting to an optical transmitter; transmitting, by the optical transmitter, a line cutting message together with another message to a corresponding power station; and informing the main control unit when a test signal is received from the power station at the optical receiver; When the main controller detects the reception of the test signal. Generating an alarm cancel message and outputting the message to the data transmitter; inserting a message according to the alarm cancel in the data transmitter into an overhead and outputting the message to the optical transmitter; and the optical transmitter is overhead together with other messages. Is transmitted to the corresponding power station, and the overhead inserted by the data transmitter is inserted into the positions D1 (D1) to D3 (D3) of the overhead according to the synchronous digital hierarchy (SDH) and output. It is characterized by.

la. Important uses of the invention

Used in optical transmission system.

Description

CONTROLLING METHOD FOR OUTPUTTING OPTIC SIGNAL IN TRANSMISSION SYSTEM}

The present invention relates to a method for controlling the output of an optical signal in a transmission system, and more particularly, to a method for controlling the output of an optical signal through a warning signal.

Typically, a transmission system transmits and receives data by connecting between switching systems or by connecting a switching system and subscribers. The transmission system connecting the switching systems is generally a transmission system using an optical signal. In the transmission system connecting the subscriber and the switching system, the connection with the switching system is connected through the optical signal, and the line to the subscriber is still coaxial. It is configured using a cable or the like. However, future transmission systems will also be connected via optical cables or optical lines to the lines to each subscriber.

Such a transmission system is classified into a transmission system having an amplifier and a transmission system having no amplifier for amplifying an optical signal during transmission. The amplifier of such an optical transmission system performs an operation of blocking an optical signal in addition to only amplifying an optical signal. That is, a transmission system without an optical amplifier cannot block an optical signal by itself. This will be described with reference to FIG. 1.

1 is a configuration diagram in which two optical transmission systems are connected. The case where both the first optical transmission system 100 and the second optical transmission system 200 are equipped with an optical amplifier will be described first. The first optical transmission system 100 separates data to be split from signals received as optical signals from the west, combines data to be combined with the transmission signal, amplifies the optical signal using an optical amplifier, and then the second optical transmission system 200. To send. The optical signal received from the second optical transmission system 200 is also transmitted to the first optical transmission system 100 in the west after the process of branching and combining as described above. When the optical cable is disconnected from the first optical transmission system 100 to the second optical transmission system 200 while transmitting data as described above, the second optical transmission system 200 loses a signal of a loss of signal (hereinafter referred to as LOS). And frame loss (hereinafter referred to as LOF) are detected. Then, the controller of the second optical transmission system 200 outputs a command to the optical amplifier to stop the output of the optical signal output to the first optical transmission system 100. Accordingly, the optical amplifier stops the signal output to the first optical transmission system 100. Then, the first optical transmission system 100 detects the LOS and the LOF. Therefore, the first optical transmission system 100 outputs a control signal for stopping the optical signal output to the second optical transmission system 200 to the optical amplifier. As a result, the optical signal is not output to the optical path between the optical transmission systems 100 and 200 on both sides. Since such optical amplifiers are very expensive equipments, there is a problem in that the cost burden of the optical transmission system increases when the optical amplifier is installed in addition to all the optical transmission systems. Therefore, when constructing an optical transmission network, only a few specific optical transmission systems are equipped with optical amplifiers.

Next, a case in which the first optical transmission system 100 includes an optical amplifier and the second optical transmission system 200 does not include an optical amplifier will be described. As such, when the first optical transmission system 100 includes the optical amplifier, when the optical path connected to the first optical transmission system 200 is cut, the second optical transmission system 200 detects the LOS and the LOF. Accordingly, the second optical transmission system 200 should block the optical signal but cannot block the optical signal since the second optical transmission system 200 does not include the optical amplifier. Therefore, the first optical transmission system 100 may not recognize the cutting of the optical path that is connected to the second optical transmission system. Therefore, the optical signal output to the first optical transmission system 100 is continuously output.

Meanwhile, the transmission systems are managed in connection with the network management system for the maintenance of the transmission network. Therefore, the operator of the network management system can recognize the state in which the optical fiber is cut through the LOS and LOF received by the network management system when the optical fiber is cut as described above. However, when the optical path is cut as described above, the operator of the network management system forcibly blocks the optical output of the optical transmission system.

However, when the operator of the network management system is not aware of this, the first optical transmission system 100 continuously outputs an optical signal, which causes a problem of shortening the lifespan of an optical transmitter which is expensive equipment. In addition, if the operator of the optical transmission system repairs the optical path without blocking the output of the optical signal, there is a case that an injury such as blindness or an accident occurs. In addition, the operator of the system was inconvenient to replace the optical path by forcibly blocking the optical signal output of the optical transmission system when replacing the optical path, and to unblock the optical signal again. Therefore, if the optical signal output of the optical transmission system is not released after the replacement of the light beam, there was a problem that the service is not continuously.

Therefore, an object of the present invention is to provide an optical signal output control method for smooth maintenance by blocking the output of the optical signal to the other optical transmission system when the optical path is cut in the optical transmission system having an optical transmitter that can not block the optical signal. In providing.

Another object of the present invention is to provide an optical signal output control method capable of resuming output of an optical signal when the optical path is cut and restored in an optical transmission system having an optical transmitter that cannot block the optical signal.

1 is a configuration diagram in which two optical transmission systems are connected;

2 is a block diagram of an optical transmission system;

3 is a control flowchart of cutting lines in an optical transmission system without an optical amplifier according to a preferred embodiment of the present invention;

4 is a control flow diagram when receiving a line cut message in a transmission system with an optical amplifier in accordance with a preferred embodiment of the present invention.

The present invention for achieving the above object is a method of controlling the optical signal output of the power transmission system when the line is cut in the optical transmission system without an optical amplifier, the main control unit detects the cutting alarm signal according to the cutting of the line from the optical receiver And checking whether the main control unit generates a line cutting message to be transmitted to the power station and outputs the data to the data transmission unit. Inserting a line cutting message into the overhead and outputting it to the optical transmitter; transmitting, by the optical transmitter together with another message, the line cutting message to the corresponding power station; and when a test signal is received from the power station at the optical receiver. Informing the main control unit, and the main control unit Generating an alarm cancel message to the data transmitter when receiving a test signal, and inserting a message according to the alarm off from the data transmitter into the overhead and outputting the message to the optical transmitter; The transmitter is configured to transmit the overhead along with other messages to the corresponding power station, and the overhead inserted by the data transmitter is based on D1 through D3 (D1) of overhead according to the synchronous digital hierarchy (SDH). And inserts it in the position of D3).

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The same parts also use the same reference numerals, although shown in the other figures.

2 is a block diagram of an optical transmission system according to the present invention. Hereinafter, the operation of the optical transmission system according to the present invention will be described in detail with reference to FIG. 2. In addition, in the description of FIG. 1, the optical transmission system of FIG. 2 is assumed to be a second optical transmission system without an optical amplifier.

The main control unit 211 controls the overall operation of the optical transmission system. In particular, according to the present invention, the main control unit 211 inspects an optical signal reception state with a large power, and generates and outputs a message to transmit data according to the checked result to the large power. The light receiving unit 212 receives an optical signal received from a power transmission system in the west and a power transmission system in the east, detects the LOS and the LOF, and outputs them to the main controller 211, and the data according to the optical paths transmitted from the power. Is separated and output to the data transmission unit 214. In addition, the optical receiver 212 outputs data included in the overhead to the data transmitter 215, and other data to the branch combiner 213. The branch combiner 213 branches the signal received from the optical receiver 212 and outputs it to the lower part, and combines the signal received from the lower part with a signal to be transmitted to the other station to output to the optical transmitter 214. The optical transmitter 214 outputs an optical signal under the control of the main controller 211, and transmits data received from the data transmitter 215 according to a synchronous digital hierarchy (SDH). Insert it into the header of Channel: DCC) and send it to the power station.

The data transmitter 215 analyzes the data received from the power station through the optical receiver 212, and outputs the analyzed result to the main controller 211 through the dual port memory 216. Then, the data received from the main controller 211 through the dual port memory 216 is output to the optical transmitter 214 and transmitted to the power station. Data output from the optical receiver 212 to the data transmitter 215 is transmitted to the data communication channel according to the synchronous digital hierarchy. The data transmission unit 215 detects data according to the line according to the present invention by inspecting D1 to D3 among overhead data transmitted from a large power station, and uses the dual port memory 216 to detect the main data using the main control unit ( 211). In addition, when data from the main control unit 211 through the dual port memory 216 is received according to the cutting of the optical path is inserted into the headers D1 to D3 of the data communication channel and output to the power station through the optical transmitter 214.

The dual port memory 216 performs an interface of data transmitted and received between the data transmitter 215 and the main controller 211. The memory 217 stores control data of the transmission system, and in particular, control data to be performed according to the present invention. In addition, the memory 217 temporarily stores data generated during the control of the main controller 211 or stores various databases to provide related data to the main controller 211.

3 is a control flowchart of cutting lines in an optical transmission system without an optical amplifier according to a preferred embodiment of the present invention. Hereinafter, a process of detecting a line cut and a process of delivering a message to a power station according to the present invention will be described in detail with reference to FIGS. 1 to 3.

The main control unit 211 performs a transmission mode in step 300. The transmission mode refers to receiving data from the west transmission system and the east transmission system, branching and combining the data, and transmitting the data to the west transmission system and the east transmission system. The main control unit 211 performs the transmission mode, and proceeds to step 302 to check whether a signal according to the cutting alarm is received from the light receiving unit 212. The signal according to the cutting alarm is examined in a cutting state when signals such as LOS and LOF are detected from the light receiving unit 212. When the cutting alarm is detected, the main control unit 211 proceeds to step 304 to generate a message to be transmitted to the power. The main control unit 211 proceeds to step 306 to output the generated message to the data transmission unit 215. As described above, the data transmission unit 215 checks the message to be transmitted to the power station and inserts it into D1 to D3 of the overhead of the SDH and outputs it to the optical transmitter 214 in the case of the message according to the optical fiber cut. Upon receiving this, the optical transmitter 214 outputs a message inserted in the overhead together with data to a corresponding power station.

The main control unit 211 proceeds to step 308 to perform a mode according to the cutting line for the power cut off the track. The main control unit 211 proceeds to step 310 to check whether the alarm release message is received. This alarm can be confirmed by checking whether the light receiving unit 212 receives the optical signal from the power. That is, the light receiving unit 212 notifies the main control unit 211 of receiving the test signal because the line is restored when the test signal is received from the western power when the line connected to the western power is cut. Through this, the main control unit 211 examines that the alarm is released. When the alarm of the inspection line is released as described above, the main controller 211 proceeds to step 312 to generate an alarm release message, and proceeds to step 314 to output the data to the data transmission unit 214. The data transmission unit 214 then receives it, inserts it into the overhead, and outputs it to the power station. This allows the large country to know the release of the alarm.

4 is a control flowchart of receiving a message when cutting a line in a transmission system having an optical amplifier according to a preferred embodiment of the present invention. Hereinafter, a process of controlling an output of an optical signal in a transmission system having an optical amplifier according to the present invention will be described in detail with reference to FIGS. 1 to 4. In addition, in the following description, FIG. 2 is described as an optical transmission system equipped with an optical amplifier, and the optical amplifier is described as being included in the optical transmitter 214.

The main control unit 211 performs a transmission mode in step 320. In this transmission mode, the LOS, LOF, etc. are detected from the optical receiver 212, branching is controlled, and optical transmission is controlled. In addition, the data transmitter 215 detects overhead data received from the optical receiver 212 and outputs the overhead data to the main controller 211 through the dual port memory 216. The main control unit 211 performs a transmission mode and proceeds to step 322 to check whether a power message is received from the data transmission unit 215 through the dual port memory 216. When the main control unit 211 receives the play message, the main control unit 211 proceeds to step 324 and checks whether the received play message is the line cutting message. The main control unit 211 proceeds to step 328 when the line cutting message is received, and proceeds to step 326 when the line cutting message is not performed.

In operation 328, the main controller 211 blocks the output of the signal to the corresponding power station in which the line is cut by controlling the optical amplifier provided in the optical transmitter 214, and performs the blocking mode in operation 330. In this case, the blocking mode is to transmit data to the other side when the optical transmission system is configured in a ring shape, and discards the data in the case of linearity. The main control unit 211 proceeds to step 322 to check whether a predetermined time has elapsed. If the predetermined time has elapsed, the main controller 211 proceeds to step 334, and if the predetermined time has not elapsed, the process proceeds to step 3360. Here, the predetermined time means a periodic time for outputting a test signal. The time value may be changed by the operator of the transmission system or at the time of manufacture of the system. If the process proceeds to step 334, the optical transmitter 214 is controlled to output a test signal to the corresponding power station that cuts off the signal output, and resets the time for the test, and the main controller 211 performs the step 330. Proceed to

In contrast, if the flow proceeds to step 336, the main controller 211 determines whether a release message is received from the data transmitter 215 through the dual port memory 216. The alarm cancel message is a message output and transmitted in steps 312 to 314 of FIG. 3. Accordingly, the overhead header is extracted from the light receiver 212 and output to the data transmitter 215. The data transmitter 215 receives the output header and outputs the header to the main controller 211 through the dual port memory 216. Therefore, through this, the main control unit 211 may receive the alarm release message. The main control unit 211 proceeds to step 338 when the alarm release message is received, and proceeds to step 330 when the alarm release message is not received. When the main control unit 211 proceeds to step 338, the main controller 211 releases the blocking of the output of the optical signal in step 328 and proceeds to step 320. That is, the main control unit 211 controls to output the optical signal again. Through this, in the optical transmission system without the optical amplifier, it is possible to inform the power station of the cutting of the optical path, and the power station can receive the control and control the output of the optical signal.

As described above, in the optical transmission system without the optical amplifier, it is possible to inform the large station that the optical path has been cut, and the large station has the advantage of controlling the output of the optical signal by receiving it.

Claims (5)

In the optical signal output control method of the power transmission system when the line is cut in the optical transmission system without an optical amplifier, Checking whether the main control unit detects a cutting alarm signal according to the cutting of the line from the light receiving unit; Generating a line cut message to be transmitted to the power unit by the main control unit when the alarm signal according to the line cut is received as a result of the inspection; Inserting, by the data transmission unit, the line disconnection message received from the main control unit into the overhead and outputting the optical transmission unit; And transmitting, by the optical transmitter, a line cutting message together with another message to a corresponding power station. The method of claim 1, Informing the main control unit when a test signal is received from the power station in the optical receiver; If the main controller detects the reception of the test signal, generating an alarm release message and outputting the generated alarm signal to the data transmission unit; Inserting a message according to the alarm release in the data transmission unit into the overhead and outputting the message to the optical transmitter; The optical transmitter further comprises the step of transmitting the overhead with the other message to the corresponding power station. The overhead of inserting in the data transmission part of Claim 1 or 2, A method of controlling an optical signal output in a transmission system characterized by inserting and outputting at positions of the diones D1 to D3 of the overhead according to the synchronous digital phase SDH. In the optical transmission system having an optical amplifier, when the line disconnect message is received in the control method of the output of the optical signal, When the line disconnect message is received from the data transmitter, controlling the optical amplifier of the optical transmitter to block an optical signal output to the corresponding line; Outputting a test signal in predetermined time units after the optical signal is blocked; Receiving an alarm release message from the data transmission unit comprises the step of restarting the output of the optical signal to the corresponding line characterized in that the optical signal output control method in the transmission system. The data cutting message and the alarm release message received from the data transmitter are inserted at positions D1 through D3 of the overhead according to the synchronous digital hierarchy SDH. Optical signal output control method in a transmission system characterized in that the message.