KR100299043B1 - Apparatus and method for processing dcc data of overhead in synchronous digital hierarchy transmission system - Google Patents

Abstract

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

An apparatus and method for processing overhead channel data in a synchronous transmission system.

I. The technical problem to be solved by the invention

Provided are an apparatus and a method for transmitting / receiving data free of optical reception period in an apparatus for processing DC channel data of an overhead head in a synchronous transmission system.

All. Summary of Solution of the Invention

The present invention relates to an overhead DC channel data processing apparatus in a synchronous transmission system, comprising: a signal processing unit for transmitting and receiving data through a line connected to another transmission system; and at least a data processing unit for processing a predetermined amount of data in the signal processing unit. And two or more transceivers, each of which is connected to a line providing transmission data, reception data, transmission clock, and reception clock, a first bus connecting each of the lines, and the bus connected to a routing unit. At least two DC processing units for processing received DC channel data and DC channel data to be transmitted, and each DC processing unit is connected to a transmission data line, a reception data line, a transmission clock and a reception clock line, respectively; A second bus connecting each of the lines and the first bus The second is connected between the buses, characterized by consisting of a routing unit and a control unit that controls the route connecting the portion for performing the connection of each line.

la. Important uses of the invention

Used in transmission system.

Description

Overhead DC Channel Data Processing Apparatus and Method for Synchronous Transmission System {APPARATUS AND METHOD FOR PROCESSING DCC DATA OF OVERHEAD IN SYNCHRONOUS DIGITAL HIERARCHY TRANSMISSION SYSTEM}

The present invention relates to an overhead processing apparatus and method for a synchronous digital hierarchy (SDH) transmission system, and more particularly, to a data communication channel (DCC) channel data processing apparatus and method.

In general, broadband transmission technology transmits data through the synchronous digital hierarchy, and the ITU-T standardized the synchronous digital hierarchy as an internationally unified digital hierarchy. Synchronous transmission systems made to this standard include synchronous transmission systems such as STM-1, STM-4, STM-16, and STM-64, and each transmission system has overhead for data transmission. This overhead is the information needed to operate and manage the network. For example, to transmit information such as alarm information notifying an operator who manages a transmission network when a transmission error or a specific system breakdown occurs in the transmission network, information for performing a system test, recovery of a system, and transfer control information. use.

There are two types of such overheads: section overhead (SOH) and path overhead (POH). The section overhead can also be divided into a player section overhead and a multiplexer section overhead, in which the DC channel data is inserted and transmitted at a predetermined position. The configuration of the header into which the DC channel data is inserted is described in detail on pages 168 to 174 of the 'Broadband Information Communication' issued in 1996, 4th edition. It is configured differently according to the specification of the transmission system. Then, the connection configuration of the optical transmission system having 10Gbps (Bit per second) will be described with reference to FIG. 1. 1 is a connection diagram of an optical transmission system having a transmission rate of 10 Gbps. The optical transmission system 20 having a transmission rate of 10 Gbps is connected to the optical transmission system 10 having a transmission rate of 10 Gbps on the left side through the optical path and the optical transmission system 30 having a transmission rate of 10 Gbps on the right side through the optical path. The lower part of the optical transmission system 20 is connected to sub-systems having 155 Mbps or 622 Mbps or 2.5 Gbps.

Next, the configuration and operation of an internal block for processing DCC data in the optical transmission system will be described with reference to FIG. 2. 2 is a main block diagram for processing DC data in an optical transmission system. The optical signal processing unit 100 includes a plurality of transmission and reception units therein, and transmits and receives data with transmission systems connected to left and right sides. In this case, data transmitted and received is processed including an overhead. In this case, the data of the hate portion of the data received by the first transmitter / receiver 110A is input to the data processor 200. The data processor 200 includes first DCC processor 220A to N-th DCC processor 220N. Each DCC processing unit 220A, ..., 220N is connected to the control unit 210 and outputs DCC channel data transmitted. The controller 210 inspects data received from each of the DCC processing units 220A, ..., and 220N to control routing according to network management and data transmission, and the controller 210 is connected to an operator computer and the like. Process input data. In addition, the data received by the optical signal processing unit 100 is input to the branch coupling unit 300 after removing the header. In addition, the branch coupling unit 200 is composed of a plurality of branch coupling boards (310A, ... 310M), each board is connected to the subsystem to transmit and receive data.

In the configuration of FIG. 2, each DCC processor of the data processor is matched 1: 1 with each optical signal transceiver of the optical signal processor 100. Therefore, when one particular optical signal transceiver fails or one particular DCC processor fails, both the boards may not operate, and thus a device capable of operating normally may also stop. Therefore, there is a problem in that all data transmitted and received through the board should be discarded or blocked by the operator.

If the data is discarded as described above, a problem arises in that it is impossible to transmit and receive accurate information between transmission systems. Also, if one board does not operate another board, there is data that needs to be processed through a specific line. There was a problem that could not be done.

Accordingly, an object of the present invention is to provide an apparatus and method for routing data transmitted and received between an optical signal processing unit and a DCC processing unit in a transmission system by performing routing according to mutual needs.

The apparatus of the present invention for achieving the above object is an overhead DC channel data processing apparatus in a synchronous transmission system, a signal processing unit for transmitting and receiving data through a line connected to another transmission system, and predetermined inside the signal processing unit At least two transceivers which process data by an amount of data, each of which is connected to a line providing transmission data, reception data, transmission clock and reception clock, and a first bus connecting the respective lines; The bus is connected to a routing unit, at least two DC processing units for processing received DC channel data and DC channel data to be transmitted, and each DC processing unit transmits and receives transmission data lines, reception data lines, transmission clocks, and reception clocks. Connected to lines for connecting the respective lines A second bus, coupled between the second bus and the first bus, characterized by consisting of a routing unit and a control unit that controls the route connecting the portion for performing the connection of each line.

The method of the present invention for achieving the above object is an overhead of a synchronous transmission system having at least two DC processing unit, a control unit for controlling the routing unit and the routing unit and at least two transceivers for transmitting and receiving data connected to the transmission line. A method of processing DC channel data, the method comprising: maintaining an initial connection state between the transceivers and the DC processing unit, checking whether there is an error occurrence device in the DC processing units or the transceivers, and Searching for a device to process the data when the data is transmitted / received to the generated device and performing routing accordingly, maintaining a connection according to the routed state, and a specific device among the DC processing units or the transmitting / receiving unit. To check if the data is congested And performing a routing for connecting the congested data to another device when the inspection result data is congested, and maintaining the connection according to the routed state.

1 is a connection configuration diagram of an optical transmission system having a transmission rate of 10 Gbps;

2 is a main block diagram for processing DC data in an optical transmission system;

3 is a diagram illustrating a connection between each transceiver of the optical signal processor and each DCC processor of the data processor according to an exemplary embodiment of the present invention;

4 is an exemplary view showing an internal configuration of a routing unit according to an embodiment of the present invention;

FIG. 5 is a control flowchart of a process for connecting to DC channel data in a control unit according to a preferred embodiment of the present invention.

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.

3 is a diagram illustrating a connection between each transceiver of the optical signal processor and each DCC processor of the data processor according to an exemplary embodiment of the present invention. Hereinafter, a configuration and an operation according to the present invention will be described in detail with reference to FIG. 3.

The optical signal processing unit 100 is connected to the optical line and has a first transmission and reception unit 110A, a second transmission and reception unit 110B,. And an Nth transmitter / receiver 110N, and the transceivers 110A, 110B, ..., 110N are connected to the optical line. In addition, each of the transceivers 110A, 110B, ..., 110N is connected to a bus of RXC, RXD, TXC as one output line, and a line of TXD is connected from the bus. Here, RXC and TXC are lines providing transmission and reception clocks, RXD is a line for outputting data received through the optical path, and TXD is a line for receiving data to output data received from the bus via the optical path. The bus of the optical signal processing unit 100 is connected to the routing unit 230 of the data processing unit 200. The routing unit 230 is connected to the control unit 210 of the data processing unit 200 to perform a switching operation according to the routing. In addition, the routing unit 230 is connected to the bus provided in the data processing unit 200, so that the first DCC processing unit 220A, the second DCC processing unit 220B,... It is connected to the N-th DCC processing unit 220N. Each line of each DCC processing unit 220A, 220B, ..., 220N has a line of TXC and RXC receiving a clock connected to the bus, a line of RXD receiving data, and the optical signal. The line TXD for outputting data to be output to the processor 100 is connected.

Accordingly, according to the above configuration, the routing unit 230 may control the data input to the corresponding line of each of the transceivers 110A, 110B, ..., 110N of the optical signal processor 100 under the control of the controller 210. The switching is connected to each of the DCC processing units 220A, 220B, ..., 220N.

4 is an exemplary view showing an internal configuration of a routing unit according to an embodiment of the present invention. Hereinafter, the internal configuration and operation of the routing unit 230 according to the present invention will be described in detail with reference to FIG. 4. In the above embodiment, it is assumed that the routing unit is composed of a total of eight blocks.

The signals received from the transceivers 110A, 110B, ..., 110N of the optical signal processor 100 are all input to two multiplexers 232 and 233 through one bus. The two multiplexers 232 and 233 selectively output data input through the data lines RXD1 to RXDN. In addition, the selector 231 receives a control signal and a clock signal received from the controller 210 to select data to be output from among the data input to the multiplexer. The selector 231 outputs a signal according to activation and deactivation of the two multiplexers 232 and 233. This signal is output from output terminal 4 and output terminal 8 of the selector 231. Therefore, the data inputted to the first DCC processing unit 220A does not receive and process the output of the first transmitting / receiving unit 110A as in the prior art, but the first transmitting / receiving unit 110A by the signal output from the control unit 210. Any signal from the signals output from the N th to N transmitters 110N can be output. In the present embodiment, it is assumed that eight blocks of the routing unit 230 and two multiplexers are provided in the internal block of the routing unit 230, so the output of the selector 231 is set to eight. However, different numbers may be implemented.

5 is a control flowchart of a process for connection of DC channel data in a control unit according to a preferred embodiment of the present invention. Hereinafter, a control flow at the time of processing for connection of DC channel data according to the present invention will be described in detail with reference to FIGS. 3 to 5.

First, the control unit 210 maintains the basic connection state in step 300. Here, the basic connection state means that the first transmitter / receiver 110A is connected to the first DCC processor 220A, and the second transmitter / receiver 110B is connected to the second DCC processor 220B. That is, as in the prior art, one processor is connected to one transceiver. The controller 210 checks whether an error occurs in one DCC processor or a transceiver of an optical signal in the DCC processor, or whether a concentration of data occurs in a specific transceiver and a DCC processor. When the concentration of data or an error of data occurs as a result of the inspection, it is determined whether the connection state should be changed by a memory provided in the controller 210. When the controller 210 proceeds to step 302 and changes the connection state as a result of the determination, the controller 210 outputs a signal according to the routing change to a selector of each internal block of the routing unit 230. Then, each selector provided in the routing unit 230 proceeds to step 304 to perform a routing operation according to the changed command, and proceeds to step 306 to output a routing signal. In operation 308, the controller 210 is routed to maintain a changed connection. When the process proceeds to step 310, it is again checked whether the connection state needs to be changed as in step 302.

Through this process, it is possible to change the routing of the device processing the overhead channel data of the synchronous transmission system.

As described above, in the synchronous transmission system, the connection state between the data transmission and reception unit and the DC channel data processing device of the overhead can be arbitrarily changed, so that the routing can be smoothly handled in case of error or data congestion of another device. have.

Claims (4)

In the overhead channel data processing apparatus of the synchronous transmission system, A signal processor for transmitting and receiving data through a line connected to another transmission system; At least two transceivers configured to process data by a predetermined amount of data in the signal processor; Each of the transceivers is connected to a line providing transmission data and reception data and a transmission clock and a reception clock. A first bus connecting each of the lines; The bus is connected to the routing unit, At least two DC processing units for processing received DC channel data and DC channel data to be transmitted; Each DC processor is connected to a transmission data line, a reception data line, and a line for transmitting and receiving a transmission clock and a reception clock, respectively. A second bus connecting each of the lines; A routing unit connected between the first bus and the second bus and performing connection of each line; The DC channel data processing apparatus of the overhead in the synchronous transmission system, characterized in that the control unit for controlling the connection of the routing unit. The method of claim 1, wherein the routing unit, Multiplexers having the same number as the DC processor, the bus line being input, and receiving the optional output signal; The DC channel data processing apparatus of the over-head in the synchronous transmission system, characterized in that the selector for outputting the selection signal to the multiplexer by the control signal received from the control unit. In the method for processing the DC channel data of the head in a synchronous transmission system having at least two or more DC processing unit, the control unit for controlling the routing unit and the routing unit and at least two transceivers for transmitting and receiving data connected to the transmission line, Maintaining an initial connection state between the transceiver and the DC processor; Checking whether there is a device having an error in the DC processing units or the transmitting / receiving units; When data is transmitted / received to the device in which the error occurs, finding a device to process the data and performing routing accordingly; Maintaining the connection according to the routed state. The method of claim 3, Checking whether data is congested in a particular device of the DC processing units or the transmitting / receiving units; Performing routing for connecting the congested data to another device when the test result data is congested; And maintaining the connection according to the routed state.