KR100241915B1 - Self-protection apparatus and method for order wire signal in transmission network of optical transmission system - Google Patents

Abstract

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

The present invention relates to the maintenance of an optical transmission system.

I. The technical problem the invention is trying to solve:

It aims to improve the efficiency of network maintenance by providing intelligent order wire signal protection.

All. The gist of the solution of the invention:

The present invention detects an alarm when the network structure is a point-to-point structure by determining a structure of a network currently connected through a system network structure check switch, and when the alarm is detected, an alarm generated by the E1 signal in the corresponding direction in which the alarm is generated. If the network structure is a ring structure, it detects an alarm and connects only the E1 signal in one direction when the alarm is not detected, and blocks the E1 signal in the connected direction when the alarm is detected. Implemented to connect the E1 signal in the direction.

la. Important uses of the invention:

Self-protection apparatus and method for order wire signal in transmission network of optical transmission system.

Description

Self-protection apparatus and method of order wire signal in transmission network of optical transmission system

The present invention relates to an optical transmission system, and more particularly, to an order wire signal transmitted and received through a transmission network.

Conventionally, one of the necessary methods for maintenance of a transmission network in a point to point network or a ring network is to make a voice call with an operator of an opposite station using an order wire device installed in the system. .

The order wire device transmits a voice signal using overhead data of the transmission system and thus is influenced by the operation state of the system.

When a problem occurs in a conventional device for transmitting / receiving overhead, noise is introduced into the order wire device, and the noise signal is transmitted to other locations through the order wire device, thus preventing interference even between normal devices. In order to prevent the inflow of noise as described above, a complicated circuit must be additionally configured in the apparatus for receiving the order wire or the overhead.

In addition, in the ring network structure shown in FIG. 2, which is frequently used, the order wire signal sent by the self is received by turning the ring once, and the order wire signal overlaps and interferes with noise.

In order to prevent the above phenomenon, one of A, B, C, and D one of the order wire signal transmission / reception ports should be disconnected. If you do not mind cutting off the ring structure is normal, so you can turn to the other side of the call.

For example, if station A and D are disconnected and the station A and D make a call, station A and D cannot be directly connected and make a call through station B and C. do. At this time, if the fiber is cut between station C and station D, it is impossible to make a call through station B and station C. If you connect E direction, you can connect station A and station D directly. Will be able to.

However, in order to perform the above control, the user needs to know the state of the other station directly and connect or cut the order wire signal transmission / reception port. In the absence of the user, maintenance through the order wire becomes impossible.

Accordingly, an object of the present invention for solving the above problems is to provide a method and apparatus for preventing the inflow of noise by connecting or blocking the transmission and reception ports of the E1 signal according to the alarm in a point-to-point network.

Another object of the present invention is to provide a method and apparatus for connecting or blocking an E1 signal transmission / reception port for controlling the flow of an order wire signal by checking a state of a counter station through a DC channel in a ring network.

1 is a block diagram of a typical point-to-point network of an optical transmission system.

2 is a schematic ring network diagram of an optical transmission system;

Figure 3 is a block diagram of an optical transmission system according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used for the same components, even if displayed on different drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

1 is a diagram showing the configuration of an optical transmission system according to an embodiment of the present invention.

Referring to FIG. 1, the dcc channel communication unit (DCU; DCC Channel Unit) 302 is configured to receive overhead (D1 to D3) data received from a power station from an optical transmission receiver (RU). It has a port, and provides an overhead (overhead) received through the port to the control unit (hereinafter referred to as "MPU") 303. It also has a port for receiving data to be transmitted from the MPU 303 to the power station and loading it on the overheads D1 to D3 to provide it to the optical transmission transmitter TU.

The MPU 303 is implemented using a microprocessor, and checks the light reception state to control the E1 signal port in the corresponding direction when an alarm occurs and transmits the alarm data to the power station or confirms the reception of the alarm data from the power station. Control the signal port. In other words, the MPU 303 has an output port for controlling the E1 signal and a port for checking the E1 signal control state, and provides an alarm generated when an overhead is configured for transmitting the state of the system from the TU to the power station. It has a port to detect. In addition, the RU has a port for detecting an alarm generated when the overhead is extracted from the optical received from the power station, and a system network using a dip switch so that an operator can select a network configuration of the system. It has a structural confirmation switch 304. Meanwhile, dual port RAM is used as a communication port for data transmission / reception with the DCU 302.

The order wire unit (OWU) 305 receives the E1 overhead data and converts it into a voice signal, receives the voice signal, converts it into an electrical signal, and transmits the signal to a large station through the E1 overhead. do. In addition, it receives the E1 signal received from the power station and forms a pass back to the power station to relay. On the other hand, the OWU 305 transmits / receives an E1 signal from the TU and RU 301, and if an ID such as an OWU ID is received in the received E1 signal, a signal (ring tone) sounds. It also has a latch port for controlling the E1 signal from the MPU 303, and provides a latch state to the MPU 303 so as to confirm the control state.

An optical transmission transmitter (RU) and an optical transmission receiver (TU) 301 are connected to each other to perform an interface function of mutually converting an optical signal and overhead data. The TU inserts the overhead into the SDH frame and transmits the overhead to transmit the overhead through the optical. In addition, the RU analyzes the SDH frame received through optical to extract overhead, and provides the extracted overhead to the part.

As described above, the system network structure confirmation switch 304 is a switch for checking the network structure of the currently connected network such as a ring network structure, a point-to-point network structure, and the like.

OWU ID confirmation switch 306 is a switch for confirming the call ID (call ID) used when you want to make a call.

Hereinafter, an embodiment according to the present invention will be described in detail with reference to the above-described configuration.

First, the system network structure check switch 304 determines whether the structure of the currently connected network is a point-to-point structure or a ring network structure.

If it is confirmed that the structure of the network currently connected through the system network structure check switch 304 is a point-to-point structure, the MPU 303 simply checks the RU east and west alarms of the own system. The alarm may be confirmed by an alarm detection signal provided from the optical transmission / reception apparatus 301.

When the alarm is generated by the confirmation, the E1 signal is blocked using the E1 signal control port in the corresponding direction of the OWU 305 to prevent the E1 signal from being transmitted / received to prevent the inflow of noise. Meanwhile, when the alarm is released, the OWU 305 is controlled to connect the blocked E1 signal so that the E1 signal is normally received.

As described above, when the currently connected network structure is a point-to-point structure, it is not necessary to transmit or receive the state of the system to the power station.

If the structure of the network currently connected through the system network structure check switch 304 is determined to be a ring network structure, the OWU ID is checked by the MPU 303.

First, the case in which the MPU 303 confirms its own OWU ID will be described.

When the MPU 303 determines that the OWU ID is ″ 0 ″, that is, its OWU ID, the MPU 303 provides a control signal to the OWU 305 through the control port to block the E1 east direction. The OWU 305 blocks the east direction E1 signal and connects the west direction E1 signal by the control signal. In the normal operation state, that is, the state in which the data transmission is normally performed because the optical transmission path to which data is to be transmitted is not cut, it is operated in the above-described configuration. In the normal operation as described above, the MPU 303 transmits alarm collection request data through the dcc channel in the east direction and the west direction to check the alarm status of all stations constituting the network periodically (about 1 second). do. The alarm collection request data is data converted to be transmittable through the dcc channel in the DCU 302 by the control of the MPU 303. However, the data to be transmitted is set with no alarm.

At this time, when the alarm is detected through the RU of the optical transmission and reception apparatus 301, the MPU 303 outputs a control signal for blocking the corresponding direction E1 signal, and the OWU 305 in the direction in which the alarm is generated by the control signal. Cut off the E1 signal and connect the E1 signal in the opposite direction.

For example, when the west direction alert is detected through the RU in the normal operation state described above, the MPU 303 outputs a control signal for blocking the west direction E1 signal. The control signal is provided to the OWU 305 to block the west direction E1 signal in which an alarm has occurred and to connect the blocked east direction E1 signal. Meanwhile, even when an east direction alarm is detected through the RU, the E1 signal is connected by the same operation.

As described above, when the area ″ 0 ″ is in the alarm state, the E1 signal is interrupted by the alarm detection, and thus it is not necessary to transmit the alarm collection request data to the power station.

Next, the operation when the MPU 303 confirms that it is not its own OWU ID will be described.

The MPU 303 confirming that it is not its OWU ID checks the RU alert by the data received through the DCU 302, and if there is no alert, transmits the received data to the OWU 305 in the opposite direction to the received direction. That is, when data is received in the east direction, the data is transmitted in the west direction, and when data is received in the west direction, the data is transmitted in the east direction.

However, when the RU alert is confirmed by the received data, the MPU 303 retransmits the received data in the received direction in addition to the received data.

At this time, the MPU 303 identified as its OWU ID analyzes the collected collection request data and detects the presence of an alarm. If it is analyzed that there is data indicating the alarm state in the returned collection request data, the E1 signal in the currently connected direction is cut off. Otherwise, if there is no data indicating the alarm state, the E1 signal in the east direction is blocked according to the normal operating state. . The absence of the alarm refers to the case where there is no alarm in both east and west directions.

By the above-described method, the OWU E1 signal can be transmitted / received to the desired location of the operator.

The present invention can effectively prevent the inflow of noise without adding complicated circuits to the order wire device used for the maintenance of the transmission device, and the OWU is flexibly controlled by interworking with the MPU in the ring structure, thereby maintaining the reliability and maintenance of the system. The maintenance function can be improved.

Claims (3)

In the optical transmission system having a self-protection function of the order wire signal by forming a transmission path according to the alarm of the transmission network, An optical transmission transmitter which transmits by inserting overhead to be transmitted through optical into a frame; An optical transmission receiver for extracting and outputting overhead by analyzing a frame received through the light; A DC channel communication unit configured to output the alarm data to be transmitted to the optical transmission transmitter or to analyze and output the alarm data at the overhead received from the optical transmission receiver; The control unit checks the light reception state through the output of the DC channel communication unit and controls the E1 signal port in the corresponding direction when an alarm occurs and transmits the alarm data to a large station or confirms the reception of the alarm data from the large station to control the E1 signal port. Wow, A system network structure check switch for selecting a network structure by a user, Self-protection apparatus of the order wire signal in the transmission network of the optical transmission system, characterized in that it comprises an order wire unit for controlling the path of the E1 overhead data under the control of the controller. In the self-protection method of the order wire signal in the optical transmission system having a self-protection function of the order wire signal by configuring the transmission path according to the alarm of the transmission network, Determining the structure of the currently connected network through the system network structure check switch, Detecting an alarm when the network structure is a point-to-point structure, and when the alarm is detected, blocking the E1 signal in the corresponding direction where the alarm occurs until the generated alarm is released; When the network structure is a ring structure, it detects an alarm and connects only the E1 signal in one direction when the alarm is not detected, and blocks the E1 signal in the connected direction and connects the E1 signal in the other direction when the alarm is detected. Self-protection method of the order wire signal in the transmission network of the optical transmission system, characterized in that consisting of a process. The method of claim 2, When the network structure is a ring structure, when an alarm is not detected, periodically transmitting alarm collection request data for checking an alarm state of a power station constituting the network; In the transmission network of the optical transmission system, if the data received in response to the alarm collection request data is analyzed to have an alarm, blocking the E1 signal in the direction in which the alarm occurred and connecting the E1 signal in the opposite direction. Self-protection method for order wire signal.

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