KR100428763B1 - Data link protection apparatus and method between exchange and remote termination - Google Patents

Abstract

The present invention relates to an apparatus and a method for protecting a data link between an exchange and a remote station by applying an IDLC (V5.2) protocol to an exchange and a centralized China section, and applying a virtual IDLC to a centralized China and a remote station section. This virtual IDLC method is a method in which the central China and the remote station independently detect the state of the data link and establish a main data link to transmit the C-channel to the normally operated data link.

To this end, the central China has a V5.2 control unit (VCU) that supports the IDLC protocol with the exchange, and is connected to each remote station by an E-1 link to support virtual IDLC with the remote station, A plurality of E-1 line unit (ELU) for providing the data link information of the VCU. In addition, the remote station supports a virtual IDLC with the ELU of the central China, and controls a common control unit (CCU) to control the overall functions of the remote station, and is connected to the ELU of the central China via the E-1 link to transmit data It includes a control relay unit (CTU).

Description

Data link protection apparatus and method between exchange and remote termination}

The present invention applies the data link protection function of the IDLC (V5.2) protocol directly to the exchange and the central office termination (COT) interval IDLC (V5.2) protocol, the central China and the remote station (Remote) Termination: RT section relates to an apparatus and method for protecting a data link between an exchange and a remote station by applying a virtual integrated digital loop carrier (IDLC) modified from the IDLC (V5.2) protocol.

In general, an optical communication network consists of an exchange, a centralized China, and a number of remote stations, as shown in FIG. Central China was used only for the fiber connection between the exchange and the remote station, and the actual IDLC protocol was between the exchange and the remote station.

In this optical network, IDLC (V5.2) standardization proposal has been proposed to protect data link between exchange and remote station. IDLC's datalink protection aims to protect the C-channel, which contains all the information related to call setup. The C-channel exists only in the primary data link or the secondary data link and is designated at least one of 16, 15, and 31 time slots of the data link.

The exchange and the remote station can transfer the data link protection message to switch the C-channel to the primary data link and the secondary data link, where the switching of the C-channel is not possible because the exchange becomes the master and the remote station becomes the slave. The exchange decides. That is, the exchange and the remote station periodically check the availability of the corresponding C-channel by exchanging a Receive Ready (RR) message through the C-channel located on the primary data link. If the RR message is not received on the C-channel of the primary datalink, that is, if the exchange first checks for an error on the C-channel, it switches the C-channel to the secondary datalink and forwards it to the remote station. On the other hand, if the remote station does not receive the RR message on the corresponding C-channel, that is, if the remote station checks the C-channel error first, the remote station requests C-channel switching to the secondary data link to the exchange. When a link transfer command is input from a remote station, the C-channel is switched from the primary data link to the secondary data link.

In the past, as described above, the IDLC protocol between the exchange and the remote station has been defined. This was possible because the centralized China located between the exchange and the remote station did not have the function of focusing, just because the exchange and the remote station were simply connected. However, as the number of subscribers increased and the capacity of the exchange was expanded, an optical communication network was proposed in which a plurality of remote stations were concentrated in a centralized China, and a plurality of centralized Chinese were concentrated at an exchange.

As such, there is a problem in that the conventional IDLC protocol cannot be directly used for data link protection in an optical communication network structure in which multiple central stations are connected to the exchange and multiple remote stations are connected to one central china.

An object of the present invention is to apply the IDLC protocol directly to a plurality of central China sections connected to the exchange and the exchange, and to any central China and the centralized China section. The present invention provides an apparatus and a method for implementing a data link protection function between an exchange and a remote station.

In order to achieve the above object, the data link protection device between the exchange and the remote station of the present invention includes a V5.2 control unit (VCU) supporting a plurality of centralized Chinese connected to the exchange and supporting an IDLC protocol with the exchange. A plurality of E-1 line units (ELUs), each connected to an E-1 link with a remote station to support a virtual IDLC with the remote station and provide data link information with the remote station to the VCU; A plurality of remote stations connected to each central China each support a virtual IDLC with the centralized Chinese ELU and control the overall functions of the remote stations, and a common control unit (CCU) that controls the entire central station. And a control relay unit (CTU) for transmitting data.

In addition, the data link protection method between the exchange and the remote station of the present invention for achieving the above object, an optical communication network consisting of a plurality of central China connected to the switch and a plurality of remote stations respectively connected to each central China In the above, the data link protection function is implemented by applying an IDLC (V5.2) protocol to the interval between the switch and the plurality of central China, and the virtual IDLC scheme is applied to the interval between the central China and the remote station. The virtual IDLC scheme is characterized in that the central China and the remote station independently detect the state of the data link and establish a main data link to transmit the C-channel to the normally operating data link.

In addition, the virtual IDLC method for achieving the above object is applied to a section between a plurality of central China connected to the exchange and a plurality of remote stations connected to each of the central China respectively to implement a data link protection function. The central China and the remote station set the data link that is normally operated at the initial operation of the system as the primary data link, and perform the virtual IDLC using the primary data link, and alert the primary data link during the virtual IDLC. Is generated and the secondary data link is in a normal operating state, resetting the normally operating secondary data link to the primary data link and performing a virtual IDLC using the reset primary data link, and performing a primary data link during the virtual IDLC. Recognizing that the data link is unavailable when an alarm occurs and the secondary data link is also in an alarm state; and when the alarm of the secondary data link is released in the disabled state, the secondary data link is released. To virtual IDLC using the reset primary datalink Characterized by including the step of performing.

1 is a structural diagram of a conventional optical communication network,

2 is a structural diagram of an optical communication network to which the present invention is applied;

3 is a block diagram of a data link protection device according to the present invention;

4 is an internal configuration diagram of the ELU and CCU shown in FIG.

5 to 7 are flowcharts illustrating operations of a data link protection method according to the present invention.

※ Explanation of code about main part of drawing ※

21: Exchange 22, 24: Central China

23, 25: remote station 22a: VCU (V5.2 Control Unit)

22b, 22c, 22d: ELU (E-1 Link Unit)

23a: CCU (Common Control Unit) 23b: CTU (Control Trunk Unit)

40a: ELU central control unit 40b: ELU data link protection switching unit

40c: ELU virtual IDLC control unit 41a: CCU central control unit

41b: CCU data link protection switching unit 41c: CCU virtual IDLC control unit

Hereinafter, a data link protection device and method between an exchange and a remote station of the present invention will be described with reference to the accompanying drawings.

2 is a structural diagram of an optical communication network to which the present invention is applied. It consists of an exchange 21, a plurality of centralized cities 22, 24 connected to the exchange 21, and a plurality of remote stations 23, 25 connected to each centralized China 22, 24, respectively.

In the present invention, the IDLC protocol is applied between the switch 21 and the centralized China 22, 24, and the virtual IDLC modified from the IDLC protocol is applied between the centralized China 22, 24 and the remote stations 23, 25. do.

The IDLC protocol applied to the section between the exchange 21 and the centralized China 22 and 24 has already been described in the prior art, and the detailed description thereof will be omitted and only the virtual IDLC will be described in detail. In the IDLC protocol, since the exchange 21 becomes the master and leads the transfer of the C-channel, and the centralized chinas 22 and 24 operate according to the instructions of the exchanged 21, the exchanged 21 and the centralized china in the transfer process. There are many messages delivered between (22, 24), and the transfer time is delayed a lot. In addition, if physical damage occurs to the data link where the C-channel is located substantially, it is not significant to transfer only some of the functions of the C-channel to another data link. The IDLC protocol, however, has such unnecessary complex features that it requires large system capacity, complexity, and delays in turnover.

Therefore, the IDLC protocol is directly applied to the section between the exchange and the central China, but the more efficient and simple virtual IDLC is applied to the section between the central China and the remote station. The virtual IDLC according to the present invention does not operate in a master / slave relationship with the central China and a remote station, but operates independently and immediately switches over the datalink when the alarm of the datalink is confirmed. In addition, when an alarm occurs in the primary data link, the entire C-channel is switched to the secondary data link.

Figure 3 is a block diagram of the internal configuration of the central China and the remote station according to the present invention. In this embodiment, it is assumed that N remote stations are connected to the central China.

The centralized China 22 has a V5.2 (V5.2 Control Unit) 22a supporting the IDLC protocol with the exchange 21, and N ELUs (E-) connected to each remote station 23 by E-1 links, respectively. 1 Line Unit) (22b, 22c, 22d). The remote station 23 has a CCU (Common Control Unit) 23a which controls the functions of the remote station as a whole, and a CTU (Control Trunk) which forms a virtual IDLC section by being connected to the ELU of the Central China 22 by an E-1 link. Unit 23b.

The VCU is a board that supports the IDLC (V5.2) protocol between the centralized China 22 and the exchange 21. The VCU 22a integrates and manages data link information of the plurality of ELUs 22b, 22c, and 22d. Therefore, the actual operation of the present invention does not occur in the VCU 22a, but is required between the centralized China 22 and the remote station 23 with a change in data link information occurring in the plurality of ELUs 22b, 22c, and 22d. Control information, that is, subscriber information of the remote station and the alarm status information, etc. are exchanged.

In each ELU 22b, 22c, 22d of the centralized China 22, a substantial data link protection function with a remote station is performed. As shown in FIG. 4, the ELUs 22b, 22c, and 22d use the ELU central controller 40a to grasp information on the current data link and the data link information received from the ELU central controller 40a. ELU data link protection switch (DPS) 40b for identifying available data link information, determining whether to switch, and transferring information on a set main data link to the VCU, and ELU data link protection. And a virtual IDLC control unit 40c for generating a C-channel using the available data link information and the transfer information transmitted from the switching unit 40b and performing a virtual IDLC with the CTU 42 of the remote station.

The CCU 41 of the remote station grasps the currently available data link information by using the CCU central control unit 41a which grasps information on the current data link and the data link information received from the CCU central control unit 41a. The C-channel is used by using the CCU Data Link Protection Switch (DPS) 41b for determining whether to switch over and the available data link information and transfer information transmitted from the CCU Data Link Protection Switch 41b. The virtual IDLC control unit 41c generates and delivers the data to the ELU 40 through the CTU 42.

The data link protection function of the centralized China ELU 40 and the data link protection function of the remote station CCU 41 are similar in configuration and function. The ELU central controller detects current data link information and integrates and manages each ELU. There is a function to inform the current data link information to the CCU central control unit is the same except that there is no such function.

Therefore, the data link protection method according to the present invention described below corresponds to both the ELU and the CCU unless further explained.

5 is a flowchart illustrating a method of protecting a data link during initial system startup of the present invention. The data link consists of a primary data link and a secondary data link. In the present invention, a data link that operates normally among the two data links is set as the main data link.

When the system starts (S51), the central control unit receives all data link information (S52), and the data link protection switching unit (hereinafter referred to as a DPS unit) searches for two data links (S53). If the alarm is confirmed at the two data links (S54), the data link is not available, so it ends immediately. However, if an alarm has not occurred in one data link (S54), the DPS unit sets a data link that is normally operated without an alarm as the primary data link and provides the virtual IDLC control unit with information about the primary data link that is operating normally. Transfer (S55). If no alarm occurs on both datalinks, set the pre-appointed datalink as the primary datalink. Then, the virtual IDLC control unit performs a virtual IDLC function using the main data link (S56). In the case of the centralized ELU, the VCU further performs information transfer on the established primary data link.

6 is an operation flowchart illustrating a data link protection method when an alarm occurs in the data link of the present invention.

During the virtual IDLC, if an alarm occurs in the main data link, the DPS unit changes the main data link to inform the virtual IDLC control unit, and the virtual IDLC control unit continuously performs the virtual IDLC using the changed main data link. Of course, if the main data link is changed, the ELU informs the VCU of the change of the main data link.

Referring to the drawings, when an error occurs in the data link while performing the virtual IDLC, and the central control unit detects an alarm (S61), the DPS unit checks whether the data link in which the alarm has occurred is a primary data link or a secondary data link. (S62). If the alarm generation data link is not the primary data link (S63) and the secondary data link, the information on the secondary data link is corrected (S64) and then terminates.

However, if the corresponding alarm occurrence data link is the primary data link (S65), it is checked whether the current secondary data link is in an alarm state (S65). If the primary data link is in an alarm state, the virtual IDLC control unit is notified of the primary data link alarm (S66), and the virtual IDLC control unit terminates the use of the corresponding main data link (S67). On the other hand, if the primary data link is not in an alarm state, the existing primary data link is switched to the secondary data link, the existing secondary data link is switched to the primary data link to change the primary data link, and modify the data link information. (S68). In addition, the DPS unit notifies the virtual IDLC control unit of the change of the primary data link (S69), and causes the virtual IDLC control unit to perform a virtual IDLC function using the primary data link (S70). In the case of the ELU, the changed data link information is notified to the DPS of the VCU so that the VCU modifies the data link information.

7 is a flowchart illustrating a method of protecting a data link at the time of releasing an alarm occurring in the data link of the present invention.

As described above, the DPS unit always designates a data link that operates normally without an alarm as the primary data link. That is, when both primary and secondary datalinks are in an alarm state and alarms are cleared on the secondary data link and become a normal link state, the DPS reassigns the normal secondary data link as the primary data link, and informs the virtual IDLC control part of the function. Make it work In the case of the ELU, the changed data link information is notified to the DPS of the VCU so that the VCU modifies the data link information.

Referring to the figure, if the central control unit detects the alarm release of the data link during the alarm of the data link (S71), the DPS unit checks whether or not the alarm release of the data link (S72). If the alerted data link is the primary data link (S73), it is checked whether a virtual IDLC operation is currently being performed (S74). If the virtual IDLC operation is currently being performed, the data link information is corrected (S75) and terminated. If the virtual IDLC operation is not being performed, the data link information is corrected (S76) and then the process proceeds to step S80.

On the other hand, if the alarm release data link is a secondary data link (S73), it is checked whether the primary data link is currently generating an alarm (S77), and if the primary data link is not in an alarm state, the information on the data link is modified ( After S78), the process ends. On the other hand, if the primary data link is in an alarm state in step S77, the existing primary data link is changed to the secondary data link, the existing secondary data link is changed to the primary data link, and the data link information is corrected (S79). In step S80, the DPS unit transfers the changed main data link information to the virtual IDLC control unit so that the virtual IDLC control unit performs a virtual IDLC function using the main data link (S81).

Although described above with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

As described above, in the virtual IDLC method of the present invention, since both sides communicating with the data link by the data link alert change the data link at the same time, the switching time is reduced and there is no message required for the switching, thereby increasing the efficiency of the system.

Claims (8)

A data link protection apparatus in an optical communication network comprising a switch, a plurality of central chinas connected to the switch, and a plurality of remote stations respectively connected to the central chinas, The central China has a V5.2 control unit (VCU) that supports the IDLC protocol with the exchange, and is connected to each remote station by an E-1 link to support virtual IDLC with the remote station, A plurality of E-1 line unit (ELU) for providing the data link information of the VCU, The remote station supports a virtual IDLC with the ELU of the central China and controls a common control unit (CCU) that controls the overall functions of the remote station, and a control relay connected to the ELU of the central China via an E-1 link to transmit data. A data link protection device between an exchange and a remote station, comprising a unit (CTU). The method of claim 1, wherein the ELU, ELU central control unit to grasp information on the current data link, The ELU data link protection switching unit (DPS) which grasps currently available data link information using the data link information received from the ELU central control unit, determines whether to switch, and delivers information on the set main data link to the VCU. Wow, And a virtual IDLC control unit for generating a C-channel using the available data link information and transfer information transmitted from the ELU data link protection switching unit and performing a virtual IDLC with a CTU of a remote station. Datalink protection device. The method of claim 1, wherein the CCU, CCU central control unit to grasp information about the current data link, A CCU data link protection switching unit (DPS) which grasps currently available data link information by using the data link information input from the CCU central control unit and determines whether to switch; And a virtual IDLC controller for generating a C-channel using the available data link information and the transfer information transmitted from the CCU data link protection switching unit and transferring the C-channel to the ELU through the CTU. Data Link Protection Device. A data link protection method in an optical communication network comprising a plurality of central China connected to an exchange and a plurality of remote stations connected to each central China, respectively, A data link protection function is implemented by applying an IDLC (V5.2) protocol to a section between the switch and the plurality of central China, and a virtual IDLC scheme is applied to a section between the central China and the remote station. Implement In the virtual IDLC scheme, the central china and the remote station independently detect the state of the data link and establish a main data link to transmit the C-channel to the normally operated data link. How to protect your datalinks. The method of claim 4, wherein the virtual IDLC scheme, The central China and the remote station setting a normal data link as a primary data link during initial system startup, and performing a virtual IDLC using the primary data link; Resetting the normally operating secondary data link to the primary data link and performing a virtual IDLC using the reset primary data link when an alarm occurs in the primary data link and the secondary data link is in a normal operating state. Wow, Recognizing that the data link is in an unusable state if an alarm occurs in the primary data link and the secondary data link also generates an alarm during the virtual IDLC; And when the alarm of the secondary data link is released in the data link unavailable state, resetting the alarm-released secondary data link to the primary data link and performing a virtual IDLC using the reset primary data link. To protect the data link between a remote station and a remote station. The method of claim 5, wherein Modifying data link information and continuously performing a virtual IDLC function using a main data link in normal operation when an alarm occurs in a secondary data link during the execution of the virtual IDLC; When the alarm of the secondary data link generated during the virtual IDLC alarm is released, further comprising the step of modifying the data link information and continuously performing a virtual IDLC function using the main data link in normal operation How to protect data link between stations. The method of claim 5, wherein Modifying data link information when the alarm of the primary data link is released in the unavailable state of the data link and performing a virtual IDLC using the released primary data link; How to protect your links. In an optical communication network composed of a plurality of central China connected to an exchange and a plurality of remote stations connected to each central China, a virtual IDLC is applied to a section between the central China and the remote station to implement a data link protection function. In the method, The central China and the remote station setting a normal data link as a primary data link during initial system startup, and performing a virtual IDLC using the primary data link; Resetting the normally operating secondary data link to the primary data link and performing a virtual IDLC using the reset primary data link when an alarm occurs in the primary data link and the secondary data link is in a normal operating state. Wow, Recognizing that the data link is in an unusable state if an alarm occurs in the primary data link and the secondary data link also generates an alarm during the virtual IDLC; And when the alarm of the secondary data link is released in the data link unavailable state, resetting the alarm released secondary data link to the primary data link and performing a virtual IDLC using the reset primary data link. IDLC method.