KR100350470B1 - Automatic path switch control apparatus in optical communication system - Google Patents

Abstract

PURPOSE: An automatic path switch control apparatus in an optical communication system is provided to optimize a transmission service by monitoring each performance state of bi-directional input/output signals and automatically selecting the most stable signal as an input signal. CONSTITUTION: A controller(40) monitors a signal state(W) by using an alarm map(50). If a signal alarm is generated, the controller(40) checks an alarm state of the opposite path. If the signal is good, the controller(40) accesses a connection data memory(52) having a connection information data through a path 'X' to check a cross connection state. Upon checking, the controller(40) sends an automatic switching command for a corresponding signal number through a path 'Y'. Then, a path selection block(54) accesses a TUDX3 time slot selection memory(56) through a path 'Z' and performs an operation on the corresponding signal number. If an alarm is also being generated from the opposite path, a path switching operation is not performed.

Description

Automatic Path Switch Control Device in Optical Communication System

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication system, and in particular, a system that requires path protection switching among 155 Mbps optical communication technology, automatically selects the most stable signal as an input signal by monitoring a signal performance state for each input / output signal in both directions. The present invention relates to a signal path selection control device for optimizing a transmission service.

Optical transmission equipment is divided into line switching system and path switching system according to protection switching. The path switching system includes path setting and automatic path selection processing technologies, among which 155Mbps optical communication equipment has been developed and sold for the purpose of automatic switching.

Patent No. 95-23998 (Invention: Signal Path Selection Control Device and Method in Optical Communication System), which was invented by the present inventors and assigned to the applicant of the present application, switches the signal path in 155 Mbps optical communication equipment (hereinafter referred to as "line transfer"). Discloses a description of control for "

Briefly describing the technique of Patent No. 95-23998 with reference to FIG. 1, a user of a track switching system by freely setting four directions (EAST, WEST, NORTH, ADD / DROP) on one cross connection block according to a path selection command. By definition, the signal direction can be freely changed for the same type.

However, in the above-described line transfer technology, the four-way path setting function only determines the type of each signal and sets only the direction desired by the user. Therefore, the default routing function of the route switching system is partially possible, but there are other things that are inadequate and need to be added. For example, it may be a part for checking an input state, a part for sending an output signal equally in both terms, and a part for allowing two input directions to be selectively changed according to the state of the input signal.

Accordingly, an object of the present invention is to monitor the signal performance status of each input / output signal in both directions in a system requiring path protection switching among the 155Mbps optical communication transmission technology, and automatically select the most stable signal as an input signal for transmission service. It is to provide a signal path selection control device to optimize.

According to the present invention described above, the present invention requires only three directions (EAST, WEST, ADD / DROP), and due to the network configuration, one system inputs the same signal in two directions (EAST, WEST) so that a better signal of the two signals Automatic selection is taken as an input, and output signals are sent in the same way in both directions. Therefore, even in the opposing system, it has a network structure that enables communication even if it is the same as its own system. And when the automatic path switching control, it adds a part to check the input state, a part to send the output signal in the same direction in both directions, and a part to select and change the two input directions according to the state of the input signal.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing the basic input / output function of the path switching system according to the present invention.

Referring to FIG. 2, a selection function block for the input and the same output function block for the output are provided. The signal path requires only three directions (EAST, WEST, ADD / DROP). When the same function signal is input in two directions (EAST, WEST), the selection function block automatically selects the better one of the two signals as the input, and the same output function block is opposed to each other because the output signal is sent in the same direction in both directions. Even if it is processed in the same way as its own system, it enables communication.

In the previously proposed line transfer technology, the four-way path setting function only determines the type of each signal and sets only the direction desired by the user. Therefore, the default routing function of the route switching system is partially possible, but there are other things that are inadequate and need to be added.

3 is a view showing the functions added and deleted in the conventional system for each item in order to achieve the new path switching system of the present invention. The list of items to be modified and added with reference to Fig. 3 is as follows.

First, the conventional line transfer system ignores the control of the NORTH portion among four directional portions including ADD / DROP (7 in FIG. 3). That is, the new route switching system according to the present invention has only three directions of ADD / DROP, EAST, and WEST.

Secondly, the new path switching system has the same signaling system in EAST and WEST except ADD / DROP. Therefore, no matter which one of the two paths is selected and used as an input signal, there should be no problem during normal operation. In the operation of the present invention, the system regulations that the same signal is sent in both directions as in the station output.

Third, the new path switching system should be equipped with the function of outputting the same signal in both directions (EAST, WEST) when the signal is output (⑨ of Figure 3).

Fourth, the new path switching system adds a function to monitor the signal state of each path and determine the state when a switching condition occurs, that is, the EAST performance monitoring function and the WEST performance monitoring function (⑤, ⑥ in FIG. 3).

Fifth, the new path switching system should automatically change the input signal selection in the direction corresponding to the direction to which the path is currently connected when the path switching is to be performed. Therefore, the path selection performed when the command to change the signal from the processor 20 is received. Add a change function (Fig. 3).

As the above-mentioned modifications and additions are to be made as an automatic path switching system without changing hardware by using only the drop connection in the existing line switching system, only two control modes are used to operate the system in two different modes. can do.

4 is a functional block diagram for the automatic path switching system of the present invention.

The overall configuration of FIG. 4 includes 30 and 32 TUPP units having functions of input signal type setting, input signal timing alignment, and signal alarm status monitoring, and input signal selection, the same output bidirectional output output, and automatic path selection when an alarm occurs. The TUDX parts 34, 36 and 38, and the controller 40 to control the whole are divided into three parts. In the TUPP part 30 and 32, the input signal input type can be set as DS1 or DS3E, and the timing of the input signal can be aligned to enable cross connection to DS1E or DS1 within the same AU3 signal format. Lines 40 and 42 connected to the input and output lines of the TUPP sections 30 and 32 are signal paths bypassed to obtain the DS3 format because the DS3 format cannot be obtained when the signals pass through the TUPP sections 30 and 32. The controller 40 monitors the state of signals input from each direction by the TUPP units 30 and 32 to determine whether there is a problem with the path being selected in advance. And if there is a problem with the path, it also checks the other direction and provides the alarm data to determine whether to automatically change the path selection state. TUDX section 34 ~ 38 has the same structure of each hardware itself, but depending on the connection status, TUDX section 34 allows signal path setting when selecting the through route from EAST to WEST or from WEST to EAST. And the TUDX unit 36 enables the function to output the same ADD input signal of the internal "B" part to EAST and WEST when sending a signal from the own station to the large station. Finally, the TUDX unit 38 is used not only to select which signal to select when receiving a signal from a large station, but also to automatically change the selected path state.

The operation of the present invention will be described based on the configuration of FIG. 4 described above. The function of the present invention is largely divided into two as described above with reference to FIG. The first is the one-way selection of the signal for the path switching system and the same output function in both directions. The second is the function of automatically changing the input signal when the signal alarm occurs.

First, in order to explain the first function, two cases will be described as an example. One example of the first case is to pass a signal from a large player without accepting it from his or her own country. Referring to FIG. 4, the controller 40 sets the signal types corresponding to Tupp1, 2 parts 30 and 32, and arrives at the TUDX1 part 34 through the respective paths, and the 'T' in the TUDX1 part 34 is 'C' and 'B' are connected to 'R' so that EAST IN is connected to WEST OUT and WEST IN is connected to EAST OUT. An example of the second case is when a country receives a signal from a large country. Referring to FIG. 4, the controller 40 sets the same signal type corresponding to TUPP1, 2 parts 30 and 32, and inputs the same to the TUDX3 part 38 through paths 44 and 46, respectively. In the TUDX3 part 38, when EAST is selected as an input signal, a signal input from "T" in the TUDX3 part 38 is connected to "R" to be input through the path 48. In addition, when WEST is selected as an input signal, the signal input from "B" in TUDX3 38 is connected to "R" to be input via path 48. In addition, when the TUDX3 part 38 transmits the signal of its own station to the counterpart in the same way in both directions, the TUDX3 part 38 receives the local station output signal input through the path 50 from the TUDX2 part 36 and receives the "B" input signal in the TUDX2 part 36. Output the same to R "and" L "for exiting paths 52 and 54. Therefore, the core function that is added differently from the cross connection of the existing line transfer system is that the TUDX2 part 36 sends the same ADD input signal to the EAST and WEST outputs. FIG. 7 is a block diagram illustrating a block outputting one input signal identically in both directions.

Next, the second function is a case where an alarm is generated in a state of a signal that is already selected and accepted as an input signal, and automatic path switching in the corresponding direction will be described below.

5 is a view showing a function for the automatic path switching. Referring to FIG. 5, the controller 40 monitors a signal state such as "W" by using the alarm map 50 of TUPP1, parts 30 and 32. If a signal alarm occurs, check the alarm status of the other path. If the signal is good, access the connection data memory 52 with the connection information data through the path "X" to check the cross connection status. If confirmed, the automatic transfer command for the corresponding signal number is given through the path "Y". The path selection block 54 then accesses the TUDX3 timeslot selection memory 56 via the path " Z " to act on the signal number. If an alarm is also generated on the other side of the path, the path switching operation is not performed. The method writes a value so that EAST or WEST can be set in the timeslot memory of the corresponding byte of the 270 timeslot bytes of the SDH frame as shown in FIG. The key function here is to check the alarm for the same signal on the opposite side when a signal alarm occurs in EAST or WEST and then perform automatic switching if there is no alarm. In addition, since the TUDX3 38 writes the address of EAST or WEST to the values of the timeslot memories according to the corresponding signals during the automatic switching operation, the switching operation can be easily processed (see FIG. 6).

As described above, the present invention implements a new automatic path switching system by adding and changing the control function based on the hardware state for the conventional line switching system. Therefore, it can be used as an existing line switching system by changing only the control state and can also be used as an automatic route switching system. Particularly in the situation where there is no automatic route switching system in Korea, the technology according to the present invention enables a ring network configuration of the route switching system.

Looking at the effect according to the present invention in detail it is described by dividing into two as follows.

The first is the effect on signal unidirectional selection and bidirectional equal output for path switching systems. The unidirectional input selection and signal output for the input direction, which is the case of the existing system, cannot satisfy the unidirectional signal selection and the same signal bidirectional output as the automatic path switching system which is the basic as the annular network equipment. Therefore, the existing system operation is not able to configure the ring network for path switching. However, the present invention satisfies the basic specification of the annular network configuration for path switching, thus enabling an annular network configuration.

The second function is to change the input signal automatically when a signal alarm occurs. This function is a practical peculiar effect of the path switching annular network, which means that when the input signal has a problem in the path, the signal input is automatically changed in the opposite path. This operation is a signaling service protection device in an annular network and is the biggest advantage compared to a linear network. In particular, this part is a function that is not available in the existing line transfer system, and it is the basis that can be used as the system of the annular network that the automatic route transfer in some cases occurs in the case of an alarm on the path. Therefore, the above two effects, the transition from the existing line transfer system to the automatic path transfer system of the present invention.

1 is a view showing an example of a four-way routing cross connection block

2 is a basic input / output function diagram of a path switching system

3 is a diagram showing functions added and deleted in the conventional system for each item in order to achieve the new path switching system of the present invention.

4 is a functional diagram for the automatic path switching system of the present invention

5 is a functional diagram for automatic path switching of the present invention

6 shows a path selection block from TUDX3 bidirectional.

7 is a block diagram of outputting one input signal identically in both directions of TUDX2.

Claims (3)

In the automatic path switching system of the annular optical communication network, An input signal unidirectional selecting means for automatically selecting and outputting a good signal for each signal by inputting a signal of the same type input in two directions; The same signal bidirectional output means for outputting the same output signal in both directions at the time of corresponding signal output; And a control means for controlling the input signal unidirectional selecting means and the same signal bidirectional output means for the same output of the input signal selection and the output signal in both directions. The method of claim 1, wherein the control means When controlling the same signal bidirectional output means, connect the time slot of the corresponding signal among the 270 time slot bytes input to one input terminal in the signal processing block to the same time slot of the two output terminals. Automatic path switch control device characterized in that. In the automatic path switching system of the annular optical communication network, First signal processing means for input signal type setting, input signal timing alignment, and signal alarm status monitoring; Second signal processing means for input signal selection, output signal bidirectional same output, and automatic path selection when an alarm occurs; Automatic path switch control device characterized in that the control means for controlling the first, second signal processing means as a whole.